Quizbank/Electricity and Magnetism: Gauss' Law/T2

calcPhyEM_2GaussQuizzes/T2 ID153728160820

For more information visit Quizbank/Electricity and Magnetism: Gauss' Law

Exams: A0 A1 A2 B0 B1 B2 C0 C1 C2 D0 D1 D2 E0 E1 E2 F0 F1 F2 G0 G1 G2 H0 H1 H2 I0 I1 I2 J0 J1 J2 K0 K1 K2 L0 L1 L2 M0 M1 M2 N0 N1 N2 O0 O1 O2 P0 P1 P2 Q0 Q1 Q2 R0 R1 R2 S0 S1 S2 T0 T1 T2

Answers: A0 A1 A2 B0 B1 B2 C0 C1 C2 D0 D1 D2 E0 E1 E2 F0 F1 F2 G0 G1 G2 H0 H1 H2 I0 I1 I2 J0 J1 J2 K0 K1 K2 L0 L1 L2 M0 M1 M2 N0 N1 N2 O0 O1 O2 P0 P1 P2 Q0 Q1 Q2 R0 R1 R2 S0 S1 S2 T0 T1 T2

60 Tests = 3 versions x 20 variations: Each of the 20 variations (A, B, ...) represents a different random selection of questions taken from the study guide.The 3 versions (0,1,..) all have the same questions but in different order and with different numerical inputs. Unless all students take version "0" it is best to reserve it for the instructor because the questions are grouped according to the order in which they appear on the study guide.

Links: Quizbank/Instructions Study guide file:QB-calcPhyEM_2GaussQuizzes-T2.pdf

Contact me at User talk:Guy vandegrift if you need any help.

T2 A0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant direction over a portion of the Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant in direction over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 A1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant direction and magnitude over the entire Gaussian surface

T2 A2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant direction and magnitude over the entire Gaussian surface

T2 B0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant direction and magnitude over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 B1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant in direction over the entire Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant direction over a portion of the Gaussian surface

T2 B2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 C0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 C1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant in direction over the entire Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

T2 C2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant direction over a portion of the Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant in direction over the entire Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 D0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

T2 D1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant in direction over the entire Gaussian surface

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 D2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant in direction over the entire Gaussian surface

b) constant direction over a portion of the Gaussian surface

c) constant magnitude over a portion of the Gaussian surface

d) constant direction and magnitude over the entire Gaussian surface

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

T2 E0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant magnitude over a portion of the Gaussian surface

d) constant direction over a portion of the Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 E1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

T2 E2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant direction and magnitude over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 F0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 F1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

T2 F2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

T2 G0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 G1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 G2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

T2 H0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant in direction over the entire Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 H1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant direction and magnitude over the entire Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

T2 H2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant direction over a portion of the Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

T2 I0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant direction over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 I1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant direction over a portion of the Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant in direction over the entire Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 I2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant in direction over the entire Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant magnitude over a portion of the Gaussian surface

d) constant direction over a portion of the Gaussian surface

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 J0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant direction over a portion of the Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant direction and magnitude over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 J1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant magnitude over a portion of the Gaussian surface

d) constant direction over a portion of the Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

T2 J2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant in direction over the entire Gaussian surface

T2 K0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant direction over a portion of the Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 K1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant direction over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 K2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant in direction over the entire Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant direction over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

T2 L0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 L1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 L2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

T2 M0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 M1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

T2 M2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

T2 N0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 N1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 N2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

T2 O0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 O1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 O2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

T2 P0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 P1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

T2 P2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

T2 Q0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 Q1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant in direction over the entire Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant direction over a portion of the Gaussian surface

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 Q2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant magnitude over a portion of the Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant direction over a portion of the Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

T2 R0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 R1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

T2 R2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

a) True

b) False

T2 S0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant in direction over the entire Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 S1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

T2 S2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant direction and magnitude over the entire Gaussian surface

c) constant in direction over the entire Gaussian surface

d) constant magnitude over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

a) True

b) False

T2 T0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant direction over a portion of the Gaussian surface

c) constant magnitude over a portion of the Gaussian surface

d) constant in direction over the entire Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

T2 T1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction over a portion of the Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant direction and magnitude over the entire Gaussian surface

d) constant in direction over the entire Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

T2 T2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

a) True

b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

a) True

b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

a) constant direction and magnitude over the entire Gaussian surface

b) constant magnitude over a portion of the Gaussian surface

c) constant direction over a portion of the Gaussian surface

d) constant in direction over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

a) True

b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

a) True

b) False

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of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys
of 10 blank lines to separate exams from keys

Key: A0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant direction over a portion of the Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant in direction over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: A1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

-d) constant direction and magnitude over the entire Gaussian surface

Key: A2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant in direction over the entire Gaussian surface

-d) constant direction and magnitude over the entire Gaussian surface

Key: B0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

-d) constant direction and magnitude over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: B1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant in direction over the entire Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant direction over a portion of the Gaussian surface

Key: B2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: C0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: C1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant in direction over the entire Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

Key: C2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant direction over a portion of the Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant in direction over the entire Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: D0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

Key: D1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant in direction over the entire Gaussian surface

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: D2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant in direction over the entire Gaussian surface

-b) constant direction over a portion of the Gaussian surface

+c) constant magnitude over a portion of the Gaussian surface

-d) constant direction and magnitude over the entire Gaussian surface

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

Key: E0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

-b) constant in direction over the entire Gaussian surface

+c) constant magnitude over a portion of the Gaussian surface

-d) constant direction over a portion of the Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: E1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

-c) constant in direction over the entire Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

Key: E2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

-d) constant direction and magnitude over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: F0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: F1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

Key: F2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

Key: G0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: G1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: G2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

Key: H0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant direction over a portion of the Gaussian surface

-d) constant in direction over the entire Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: H1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

-d) constant direction and magnitude over the entire Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

Key: H2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

-b) constant direction over a portion of the Gaussian surface

-c) constant in direction over the entire Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

Key: I0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant in direction over the entire Gaussian surface

-d) constant direction over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: I1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant direction over a portion of the Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant in direction over the entire Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: I2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant in direction over the entire Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

+c) constant magnitude over a portion of the Gaussian surface

-d) constant direction over a portion of the Gaussian surface

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: J0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant direction over a portion of the Gaussian surface

-c) constant in direction over the entire Gaussian surface

-d) constant direction and magnitude over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: J1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

-b) constant in direction over the entire Gaussian surface

+c) constant magnitude over a portion of the Gaussian surface

-d) constant direction over a portion of the Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

Key: J2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant direction over a portion of the Gaussian surface

-d) constant in direction over the entire Gaussian surface

Key: K0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant direction over a portion of the Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: K1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant direction over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: K2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant in direction over the entire Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant direction over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

Key: L0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: L1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: L2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

Key: M0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: M1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

Key: M2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

Key: N0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: N1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: N2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

Key: O0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: O1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: O2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

Key: P0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: P1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

Key: P2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

Key: Q0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

-c) constant in direction over the entire Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: Q1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant in direction over the entire Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant direction over a portion of the Gaussian surface

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: Q2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

+a) constant magnitude over a portion of the Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

-c) constant in direction over the entire Gaussian surface

-d) constant direction over a portion of the Gaussian surface

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

Key: R0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: R1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

Key: R2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated inside the Gaussian surface

-a) True

+b) False

Key: S0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant in direction over the entire Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

-c) constant direction over a portion of the Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: S1[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

-c) constant in direction over the entire Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

Key: S2[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated on the Gaussian surface

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

-b) constant direction and magnitude over the entire Gaussian surface

-c) constant in direction over the entire Gaussian surface

+d) constant magnitude over a portion of the Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

dA_{1}=dA_{3}

-a) True

+b) False

Key: T0[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

-b) constant direction over a portion of the Gaussian surface

+c) constant magnitude over a portion of the Gaussian surface

-d) constant in direction over the entire Gaussian surface

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

Key: T1[edit | edit source]

1) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

3) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

4) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction over a portion of the Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant direction and magnitude over the entire Gaussian surface

-d) constant in direction over the entire Gaussian surface

5) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

Key: T2[edit | edit source]

1) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{2}\cdot dA_{3}=0

+a) True

-b) False

2) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}+{\vec {E}}_{3}\cdot dA_{3}=0

-a) True

+b) False

3) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ had

-a) constant direction and magnitude over the entire Gaussian surface

+b) constant magnitude over a portion of the Gaussian surface

-c) constant direction over a portion of the Gaussian surface

-d) constant in direction over the entire Gaussian surface

4) In this description of the flux element,

d{\vec {S}}={\hat {n}}dA_{j}

(j=1,2,3) where

{\hat {n}}

is the outward unit normal, and a positive charge is assumed at point O, inside the Gaussian surface shown. The field lines exit at

S_{1}

and

S_{3}

but enter at

S_{2}

. In this figure,

{\vec {E}}_{1}\cdot dA_{1}={\vec {E}}_{3}\cdot dA_{3}

+a) True

-b) False

5) If Gauss' law can be reduced to an algebraic expression that easily calculates the electric field $(\varepsilon _{0}EA^{*}=\rho V^{*})$ , ${\vec {E}}$ was calculated outside the Gaussian surface

-a) True

+b) False