2025
NEET
MCQ
NEET 2025
The plates of a parallel plate capacitor are separated by $d$. Two slabs of different dielectric constant $K_1$ and $K_2$ with thickness $\frac{3}{8} d$ and $\frac{d}{2}$, respectively are inserted in the capacitor. Due to this, the capacitance becomes two times larger than when there is nothing between the plates. If $K_1=1.25 K_2$, the value of $K_1$ is:
A.
1.60
B.
1.33
C.
2.66
D.
2.33
2024
NEET
MCQ
NEET 2024 (Re-Examination)
A $12 \mathrm{~pF}$ capacitor is connected to a $50 \mathrm{~V}$ battery, the electrostatic energy stored in the capacitor in $\mathrm{nJ}$ is
A.
15
B.
7.5
C.
0.3
D.
150
2024
NEET
MCQ
NEET 2024 (Re-Examination)
The capacitance of a capacitor with charge $q$ and a potential difference $V$ depends on
A.
both $q$ and $V$
B.
the geometry of the capacitor
C.
$q$ only
D.
$V$ only
2024
NEET
MCQ
NEET 2024 (Re-Examination)
The steady state current in the circuit shown below is :
A.
0.67 A
B.
1.5 A
C.
2 A
D.
1 A
2024
NEET
MCQ
NEET 2024
In the following circuit, the equivalent capacitance between terminal A and terminal B is :
A.
2 $\mu$F
B.
1 $\mu$F
C.
0.5 $\mu$F
D.
4 $\mu$F
2024
NEET
MCQ
NEET 2024
If the plates of a parallel plate capacitor connected to a battery are moved close to each other, then
A. the charge stored in it, increases.
B. the energy stored in it, decreases.
C. its capacitance increases.
D. the ratio of charge to its potential remains the same.
E. the product of charge and voltage increases.
Choose the most appropriate answer from the options given below:
A.
A, B and E only
B.
A, C and E only
C.
B, D and E only
D.
A, B and C only
2023
NEET
MCQ
NEET 2023 Manipur
The equivalent capacitance of the arrangement shown in figure is:
A.
30 $\mu$F
B.
15 $\mu$F
C.
25 $\mu$F
D.
20 $\mu$F
2023
NEET
MCQ
NEET 2023 Manipur
To produce an instantaneous displacement current of $2 \mathrm{~mA}$ in the space between the parallel plates of a capacitor of capacitance $4 ~\mu \mathrm{F}$, the rate of change of applied variable potential difference $\left(\frac{\mathrm{dV}}{\mathrm{dt}}\right)$ must be :-
A.
$800 \mathrm{~V} / \mathrm{s}$
B.
$500 \mathrm{~V} / \mathrm{s}$
C.
$200 \mathrm{~V} / \mathrm{s}$
D.
$400 \mathrm{~V} / \mathrm{s}$
2023
NEET
MCQ
NEET 2023
The equivalent capacitance of the system shown in the following circuit is:
A.
3$\mu$F
B.
6$\mu$F
C.
9$\mu$F
D.
2$\mu$F
2022
NEET
MCQ
NEET 2022 Phase 2
The distance between the two plates of a parallel plate capacitor is doubled and the area of each plate is halved. If C is its initial capacitance, its final capacitance is equal to
A.
${C \over 4}$
B.
2C
C.
${C \over 2}$
D.
4C
2022
NEET
MCQ
NEET 2022 Phase 2
The effective capacitances of two capacitors are 3 $\mu$F and 16 $\mu$F, when they are connected in series and parallel respectively. The capacitance of two capacitors are :
A.
1.2 $\mu$F, 1.8 $\mu$F
B.
10 $\mu$F, 6 $\mu$F
C.
8 $\mu$F, 8 $\mu$F
D.
12 $\mu$F, 4 $\mu$F
2022
NEET
MCQ
NEET 2022 Phase 1
A capacitor of capacitance C = 900 pF is charged fully by 100 V battery B as shown in figure (a). Then it is disconnected from the battery and connected to another uncharged capacitor of capacitance C = 900 pF as shown in figure (b). The electrostatic energy stored by the system (b) is
A.
4.5 $\times$ 10$-$6 J
B.
3.25 $\times$ 10$-$6 J
C.
2.25 $\times$ 10$-$6 J
D.
1.5 $\times$ 10$-$6 J
2021
NEET
MCQ
NEET 2021
A parallel plate capacitor has a uniform electric field $\overrightarrow E $ in the space between the plates. If the distance between the plates is 'd' and the area of each plate is 'A', the energy stored in the capacitor is : ($\varepsilon $0 = permittivity of free space)
A.
${{{E^2}Ad} \over {{\varepsilon _0}}}$
B.
${1 \over 2}{\varepsilon _0}{E^2}$
C.
${\varepsilon _0}EAd$
D.
${1 \over 2}{\varepsilon _0}{E^2}Ad$
2021
NEET
MCQ
NEET 2021
The equivalent capacitance of the combination shown in the figure is :
A.
3C/2
B.
3C
C.
2C
D.
C/2
2020
NEET
MCQ
NEET 2020 Phase 1
The capacitance of a parallel plate capacitor with air as medium is 6$\mu $F. With the introduction of a dielectric medium, the capacitance become 30 $\mu $F The permittivity of the medium is :
$\left( {{\varepsilon _0} = 8.85 \times {{10}^{ - 12}}{C^2}{N^{ - 1}}{m^{ - 2}}} \right)$
$\left( {{\varepsilon _0} = 8.85 \times {{10}^{ - 12}}{C^2}{N^{ - 1}}{m^{ - 2}}} \right)$
A.
$1.77 \times {10^{ - 12}}{C^2}{N^{ - 1}}{m^{ - 2}}$
B.
$0.44 \times {10^{ - 10}}{C^2}{N^{ - 1}}{m^{ - 2}}$
C.
$5.00{C^2}{N^{ - 1}}{m^{ - 2}}$
D.
$0.44 \times {10^{ - 13}}{C^2}{N^{ - 1}}{m^{ - 2}}$
2019
NEET
MCQ
NEET 2019
A parallel plate capacitor of capacitance 20 $\mu $F is being charged by a voltage source whose potential is changing at the rate of 3V/s. The conduction current through the connecting wires, and the displacement current through the plates of the capacitor, would be, respectively :
A.
zero, zero
B.
zero, 60 $\mu $A
C.
60 $\mu $A, 60 $\mu $A
D.
60 $\mu $A, zero
2018
NEET
MCQ
NEET 2018
The electrostatic force between the metal plates
of an isolated parallel plate capacitor C having
a charge Q and area A, is
A.
Independent of the distance between the
plates
B.
Linearly proportional to the distance
between the plates
C.
Proportional to the square root of the
distance between the plates
D.
Inversely proportional to the distance
between the plates
2017
NEET
MCQ
NEET 2017
A capacitor is charged by a battery. The battery is removed and another identical unchanged capacitor is connected in parallel. The total electrostatic energy of resulting system
A.
decreases by a factor of 2
B.
remains the same
C.
increases by a factor of 2
D.
increases by a factor of 4
2016
NEET
MCQ
NEET 2016 Phase 2
A parallel-plate capacitor of area a, plate separation d and capacitance C is filled with four dielectric materials having dielectric constants k1, k2, k3 and k4 as shown in the figure. If a single dielectric material is to be used to have the same capacitance C in this capacitor, then its dielectric constant k is given by
A.
k = k1 + k2 + k3 + 3k4
B.
k = ${2 \over 3}$ (k1 + k2 + k3) + 2k4
C.
${2 \over k}$ = ${3 \over {{k_1} + {k_2} + {k_3}}} + {1 \over {{k_4}}}$
D.
${1 \over k}$ = ${1 \over {{k_1}}} + {1 \over {{k_2}}} + {1 \over {{k_3}}} + {3 \over {2{k_4}}}$
2016
NEET
MCQ
NEET 2016 Phase 1
A capacitor of 2 $\mu $F is charged as shown in the diagram. When the switch S is turned to position 2, the percentage of its stored energy dissipated is
A.
75%
B.
80%
C.
0%
D.
20%
2015
NEET
MCQ
AIPMT 2015
A parallel plate air capacitor has capacity C, distance of separation between plates is d and potential difference $V$ is applied between the plates. Force of attraction between the plates of the parallel plate air capacitor is
A.
${{C{V^2}} \over d}$
B.
${{{C^2}{V^2}} \over {2{d^2}}}$
C.
${{{C^2}{V^2}} \over {2d}}$
D.
${{C{V^2}} \over {2d}}$
2015
NEET
MCQ
AIPMT 2015 Cancelled Paper
A parallel plate air capacitor of capacitance C is connected to a cell of emf V and then disconnected from it. A dielectric slab of dieletric constant K, which can just fill the air gap of the capacitor, is now inserted in it . Which of the following is incorrect ?
A.
The change in energy stored is ${1 \over 2}C{V^2}\left( {{1 \over K} - 1} \right)$
B.
The charge on the capacitor is not conserved.
C.
The potential difference between the plates decreases K times.
D.
The energy stored in the capaciotor decreases K times.
2014
NEET
MCQ
AIPMT 2014
Two thin dielectric slabs of dielectric constants K1 and K2(K1 < K2) are inserted between plates of a parallel plate capacitor, as shown in the figure. The variation of electric field E between the plates with distance d as measured from plate P is correctly shown by
A.
B.
C.
D.
2012
NEET
MCQ
AIPMT 2012 Mains
A parallel plate capacitor has a uniform electric field E in the space between the plates. If the distance between the plates is d and area of each plate is A, the energy stored in the capacitor is
A.
${1 \over 2}{\varepsilon _0}{E^2}$
B.
${{{E^2}Ad} \over {{\varepsilon _0}}}$
C.
${1 \over 2}{\varepsilon _0}{E^2}Ad$
D.
${\varepsilon _0}EAd$
2011
NEET
MCQ
AIPMT 2011 Prelims
A parallel plate capacitor has a uniform electric field E in the space between the plates. If the distance between the plates is d and area of each plate is A, the energy stored in the capacitor is
A.
${1 \over 2}{\varepsilon _0}{E^2}$
B.
${{{E^2}Ad} \over {{\varepsilon _0}}}$
C.
${1 \over 2}{\varepsilon _0}{E^2}Ad$
D.
${\varepsilon _0}EAd$
2010
NEET
MCQ
AIPMT 2010 Mains
Two parallel metal plates having charges +Q and $-$Q face each other at a certain distance between them. If the plates are now dipped in kerosene oil tank, the electric field between the plates will
A.
become zero
B.
increase
C.
decrease
D.
remain same
2010
NEET
MCQ
AIPMT 2010 Prelims
A series combination of n1 capacitors, each of value C1, is charged by a source of potential difference 4V. When another parallel combination of n2 capacitors, each of value C2, is charged by a source of potential difference V, it has the same (total) energy stored in it. as the first combination has. The value of C2. in terms of C1, is then
A.
${{2{C_1}} \over {{n_1}{n_2}}}$
B.
$16{{{n_2}} \over {{n_1}}}{C_1}$
C.
$2{{{n_2}} \over {{n_1}}}{C_1}$
D.
${{16{C_1}} \over {{n_1}{n_2}}}$
2009
NEET
MCQ
AIPMT 2009
Three capacitors each of capacitance C and of breakdown voltage V are joined in series. The capacitance and breakdown voltages of the combination will be
A.
$3C,{V \over 3}$
B.
${C \over 3},3V$
C.
$3C,3V$
D.
${C \over 3},{V \over 3}$
2008
NEET
MCQ
AIPMT 2008
A parallel plate capacitor has a uniform electric field E in the space between the plates. If the distance between the plates is d and area of each plate is A, the energy stored in the capacitor is
A.
${1 \over 2}{\varepsilon _0}{E^2}$
B.
${{{E^2}Ad} \over {{\varepsilon _0}}}$
C.
${1 \over 2}{\varepsilon _0}{E^2}Ad$
D.
${\varepsilon _0}EAd$
2007
NEET
MCQ
AIPMT 2007
Two condensers, one of capacity C and other of capacity C/2 are connected to a V-volt battery, as shown in the figure. The work done in charging fully both the condensers is
A.
${1 \over 4}C{V^2}$
B.
${3 \over 4}C{V^2}$
C.
${1 \over 2}C{V^2}$
D.
2CV2
2006
NEET
MCQ
AIPMT 2006
A parallel plate air capacitor is charged to a potential difference of V volts. After disconnecting the charging battery the distance between the plates of the capacitor is increased using an insulting handle. As a result the potential difference between the plates
A.
increases
B.
decreases
C.
does not charge
D.
becomes zero
2005
NEET
MCQ
AIPMT 2005
A network of four capacitors of capacity equal to C1 = C, C2 = 2C, C3 = 3C and C4 = 4C are connected to a battery as shown in the figure. The ratio of the charges on C2 and C4 is
A.
4/7
B.
3/22
C.
7/4
D.
22/3
2003
NEET
MCQ
AIPMT 2003
Three capacitors each of capacity 4 $\mu $F are to be connected in such a way that the effective capacitance is $6\mu F.$ This can be done by
A.
connecting all of them in series
B.
connecting them in parallel
C.
connecting two in series and one in parallel
D.
connecting two in parallel and one in series
2002
NEET
MCQ
AIPMT 2002
A capacitor of capacity C1 charged upto V volt and then connected to an uncharged capacitor of capacity C2. The final potential difference across each will be
A.
${{{C_1}V} \over {{C_1} + {C_2}}}$
B.
${{{C_2}V} \over {{C_1} + {C_2}}}$
C.
$\left( {1 - {{{C_2}} \over {{C_1}}}} \right)V$
D.
$\left( {1 + {{{C_2}} \over {{C_1}}}} \right)$
2001
NEET
MCQ
AIPMT 2001
Energy per unit volume for a capacitor having area A and separation d kept at potential difference V is given by
A.
${1 \over 2}{\varepsilon _0}{{{V^2}} \over {{d^2}}}$
B.
${1 \over {2{\varepsilon _0}}}{{{V^2}} \over {{d^2}}}$
C.
${1 \over 2}C{V^2}$
D.
${{{Q^2}} \over {2C}}.$
2000
NEET
MCQ
AIPMT 2000
A capacitor is charged with a battery and energy stored is U. After disconnecting battery another capacitor of same capacity is connected in parallel to the first capacitor. Then energy stored in each capacitor is
A.
$U/2$
B.
U/4
C.
4U
D.
2U