Deck 26: Capacitors and Dielectrics

A) $C = V / Q$
B) $C = Q ^ { 2 } V$
C) $C = Q V$
D) $C = Q / V$

A) $1.5 \times 10 ^ { - 12 } \mathrm {~F}$
B) $2.6 \times 10 ^ { - 12 } \mathrm {~F}$
C) $5.1 \times 10 ^ { - 13 } \mathrm {~F} \text {. }$
D) $6.5 \times 10 ^ { - 13 } \mathrm {~F}$

A) $4.6 \times 10 ^ { - 12 } \mathrm { C }$
B) $8.5 \times 10 ^ { - 12 } \mathrm { C }$
C) $1.5 \times 10 ^ { - 11 } \mathrm { C }$
D) $3.1 \times 10 ^ { - 11 } \mathrm { C } \text {. }$

A) smaller-radius shell.
B) larger-radius shell.
C) neither; both have the same capacitance.
D) unknown; we need to know the potential of each shell.

A) the charge on the plates.
B) the potential across the plates.
C) the geometry of the plates (area and separation).
D) both (a) and (b).

A) 1.2 mV.
B) 520 mV.
C) 802 V.
D) 8.0 V.

A) the potential reaches zero.
B) the plates touch.
C) the charge (on one of the plates) reaches zero.
D) the dielectric breakdown of the air occurs.

A) coulomb/volt.
B) voltcoulomb. .
C) volt/coulomb.
D) amperecoulomb. .

A) 0 F.
B) 43 pF.
C) 36 pF.
D) 22 pF.

A) 2.8 $\mu$ F
B) 53 pF.
C) 21 pF.
D) 18 $\mu$ F.

A) $7.6 \times 10 ^ { - 10 } \mathrm { C }$
B) $5.1 \times 10 ^ { - 10 } \mathrm { C } \text {. }$
C) $2.5 \times 10 ^ { - 10 } \mathrm { C }$
D) $1.3 \times 10 ^ { - 10 } \mathrm { C }$

A) 170 N/C.
B) 11,000 N/C.
C) 1700 N/C.
D) 5600 N/C.

A) $8.6 \times 10 ^ { 3 }$ N/C.
B) $4.4 \times 10 ^ { 6 }$ N/C.
C) $7.5 \times 10 ^ { 4 }$ N/C.
D) $1.6 \times 10 ^ { 5 }$ N/C.

A) 0.5 F.
B) 2 F.
C) 3 F.
D) 6 F.

A) 0.5 F.
B) 2 F.
C) 3 F.
D) 6 F.

A) 3.3 C.
B) 0.26 C.
C) 1.2 C.
D) 0.16 C.

A) $A B C / ( A + B + C )$
B) $( A + B + C ) / ( A B C )$
C) $A + B + C$
D) $A B C / ( A B + B C + C A )$

A) $A B C / ( A + B + C )$
B) $( A + B + C ) / ( A B C )$
C) $A + B + C$
D) $A B C / ( A B + B C + C A )$

A) is 3 A.
B) is A/3.
C) is A.
D) cannot be determined (we need to know A).

A) 0 F.
B) $\infty \mathrm { F } .$
C) $6 / \pi ^ { 2 } \mathrm {~F} .$
D) 3/7 F.

A) 0 F.
B) $\infty \mathrm { F } .$
C) $6 / \pi ^ { 2 } \mathrm {~F} .$
D) 3/7 F.

A) 30,000 N/C.
B) 15,000 N/C.
C) 4800 N/C.
D) 2100 N/C.

A) 2500 N/C.
B) 3100 N/C.
C) 4300 N/C.
D) 6200 N/C.

A) 180 $\mu$ F.
B) 1400 $\mu$ F.
C) 2100 $\mu$ F.
D) 620 $\mu$ F.

A) 1800 N/C.
B) 2600 N/C.
C) 780 N/C.
D) 3800 N/C.

A) $7.1 \times 10 ^ { - 8 }$ J.
B) $5.5 \times 10 ^ { - 9 }$ J.
C) $1.4 \times 10 ^ { - 8 }$ J.
D) $8.6 \times 10 ^ { - 9 }$ J.

A) 22 V.
B) 15 V.
C) 11 V.
D) 7.1 V.

A) 71 mJ.
B) 8.5 mJ.
C) 130 mJ.
D) 42 mJ.

A) $5.1 \times 10 ^ { - 5 } \mathrm {~J} / \mathrm { m } ^ { 3 } \text {. }$
B) $6.3 \times 10 ^ { - 7 } \mathrm {~J} / \mathrm { m } ^ { 3 }$
C) $9.5 \times 10 ^ { - 5 } \mathrm {~J} / \mathrm { m } ^ { 3 }$
D) $7.5 \times 10 ^ { - 6 } \mathrm {~J} / \mathrm { m } ^ { 3 }$

A) $1.7 \times 10 ^ { - 5 }$ J/m $3$
B) $2.9 \times 10 ^ { - 7 }$ J/m $3$
C) $5.6 \times 10 ^ { - 5 }$ j/m $3$
D) $8.5 \times 10 ^ { - 6 }$ j/m $3$

A) $\pi \varepsilon _ { 0 } R ^ { 2 }$
B) $4 \pi \varepsilon _ { o } R ^ { 2 }$
C) $\pi \varepsilon _ { 0 } R$
D) $4 \pi \varepsilon _ { 0 } R$

A) multiplying it by the dielectric constant squared.
B) multiplying it by the dielectric constant.
C) dividing it by the dielectric constant.
D) dividing it by the dielectric constant squared.

A) The capacitance remains constant and the charge decreases.
B) The capacitance increases and the charge remains constant.
C) The capacitance increases and the charge increases.
D) The capacitance remains constant and the charge increases.

A) E².
B) E.
C) $\sqrt { E }$
D) ln E.

A) larger than it is far from the ends.
B) the same as it is far from the ends.
C) smaller than it is far from the ends.
D) Hold it! The concept loses its meaning near the ends.

A) it is an unsolved problem of physics.
B) a straightforward calculation produces an infinite answer.
C) its constant value renders it irrelevant where energy differences account for observable effects.
D) Hold it! There are no exceptions.

A) all possible charge pairs.
B) specially selected charge pairs.
C) specially selected charge groups (not pairs).
D) none of the above.

A) only for ideal parallel plates with no fringing.
B) only for plates with a rectangular surface area.
C) only for plates that conduct perfectly.
D) for any E-field distribution.

A) electric charge.
B) electric fields.
C) Both of the first two responses are valid.
D) Neither of the first two responses is valid.