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HC Verma Test: Electrostatic Potential & Capacitance - JEE MCQ


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30 Questions MCQ Test Physics for JEE Main & Advanced - HC Verma Test: Electrostatic Potential & Capacitance

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*Multiple options can be correct
HC Verma Test: Electrostatic Potential & Capacitance - Question 1

The figure shows a diagonal symmetric arrangement of capacitors and a battery

If the potential of C is zero, then   

HC Verma Test: Electrostatic Potential & Capacitance - Question 2

The capacitance of a metallic sphere will be 1mF, if its radius is nearly

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 2

The expression of capacitance of metallic sphere is C=4πϵ0​r (The capacitance of a single spherical conductor means that we imagine a spherical shell of infinite radius surrounding the first conductor.)
Therefore,

 r = C/4πϵ​0

= 10 − 6 × 9 × 109 = 9 × 103 m = 9km

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*Multiple options can be correct
HC Verma Test: Electrostatic Potential & Capacitance - Question 3

Two capacitors of capacitances 1mF and 3mF are charged to the same voltages 5V. They are connected in parallel with oppositely charged plates connected together. Then

HC Verma Test: Electrostatic Potential & Capacitance - Question 4

Two spherical conductors A and B of radii R and 2R respectively are each given a charge Q. When they are connected by a metallic wire. The charge will

HC Verma Test: Electrostatic Potential & Capacitance - Question 5

The capacity of a parallel plate condenser is C. Its capacity when the separation between the plates is halved will be

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 5

The capacity of a parallel plate condenser is given as,
C=εA/​d
When the separation between the plates is halved then the new capacity of the condenser is given as,
C′=εA​/(d/2)​
C′=2C
Thus, the new capacity of parallel plate condenser is 2C.

HC Verma Test: Electrostatic Potential & Capacitance - Question 6

If the p.d. across the ends of a capacitor 4mF is 1.0 kilovolt. Then its electrical potential energy will be

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 6

HC Verma Test: Electrostatic Potential & Capacitance - Question 7

The energy of a charged capacitor resides in

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 7

The energy of a charged capacitor resides in both electric and magnetic fields .
Energy resides in the electric field because of the charges on the capacitor.
Energy resides in the magnetic field because of The Maxwell's displacement current in the capacitor.
 

HC Verma Test: Electrostatic Potential & Capacitance - Question 8

The capacitance of a parallel plate condenser does not depend upon

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 8

The capacitance C is the amount of charge stored per volt, or C=QV. The capacitance of a parallel plate capacitor is C=ϵ0Ad, when the plates are separated by air or free space.

HC Verma Test: Electrostatic Potential & Capacitance - Question 9

The energy density in a parallel plate capacitor is given as 2.2 × 10-10 J/m3. The value of the electric field in the region between the plates is -

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 9

 

 

 

HC Verma Test: Electrostatic Potential & Capacitance - Question 10

Two capacitances of capacity C1 and C2 are connected in series and potential difference V is applied across it. Then the potential difference acros C1 will be

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 10

HC Verma Test: Electrostatic Potential & Capacitance - Question 11

A conductor of capacitance 0.5mF has been charged to 100volts. It is now connected to uncharged conductor of capacitance 0.2mF. The loss in potential energy is nearly

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 11

Given,
C1=0.5 mf
C2=0.2mf
V=100v
So,
U=(1/2) CTV2
CT=C1C2/XC1+C2=(0.5x0.2/0.5+0.2)mf
CT=0.14mf
U=(1/2)(0.14mf)(100V)2
=(10.07x1-6x104)J
=(7x10-2x10-6x104)J
=7x10-4J

HC Verma Test: Electrostatic Potential & Capacitance - Question 12

Two spherical conductors of capacitance 3.0mF and 5.0mF are charged to potentials of 300volt and 500volt. The two are connected resulting in redistribution of charges. Then the final potential is

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 12

First find the charge in 1st capacitor
Q1= C1xV1
=0.003*300
=0.9 C
Similarly, find Q2
i.e. Q2=2.5 C
After connecting the capacitors in parallel you get a net capacitance C=8 mF (c1+c2).
Thus, final potential is V=Q/C
Q=Q1+Q2=3.4 C
V=3.4/0.008
= 425 V
 

HC Verma Test: Electrostatic Potential & Capacitance - Question 13

A parallel plate capacitor of capacitance C is connected to a battery and is charged to a potential difference V. Another capacitor of capacitance 2C is similarly charged to a potential difference 2V. The charging battery is now disconnected and the capacitors are connect in parallel to each other in such a way that the positive terminal of one is connected to the negative terminal of the other. The final energy of the configuration is

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 13

Where N is the number of turns of the toroid coil, I is the amount of current flowing and r is the radius of the toroid.
As both capacitors are in parallel so equivalent capacitance Ceq​=C+2C=3C .
Net potential, Vn​=2V−V=V
Energy stored, U=(1/2)​Ceq​Vn2​=(1/2)×3CV2=(3/2)​CV2

HC Verma Test: Electrostatic Potential & Capacitance - Question 14

A 2μF capacitor is charged to a potential = 10 V. Another 4μF capacitor is charged to a potential = 20V. The two capacitors are then connected in a single loop, with the positive plate of one connected with negative plate of the other. What heat is evolved in the circuit?

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 14

Charge on 2μf capacitor=10vx2μF=20μC=Q1
Charge on 4μf capacitor=4μFx20v=80μC=Q2
Now, these capacitors are connected in a single loop in given manner,

Now after transfer,

Applying loop rule,
(q/2)+[(60+q)/4]=0=>q=-20μC

Now, drop across the capacitors is,
ΔVf=40/4v=10v
Final energy stored in capacitor=Uf
= (1/2) (C1+C2)(ΔVf)2=1/2 x6 x100uf=300 μf
Initial energy stored in capacitor=Ui
= (1/2) C1V12+(1/2) C2V22=(1/2)x2x100+ (1/2)x4x400=900 μf
Now, heat evolved in the circuit will be,
Ui-Uf= (900-300) μf=600 μf
Thus, the correct answer would be option B.

*Multiple options can be correct
HC Verma Test: Electrostatic Potential & Capacitance - Question 15

The figure shows a diagonal symmetric arrangement of capacitors and a battery
Identify the correct statements.

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 15

If 2μF where not present between B and D, then potential drop across upper 4μF will be less than potential drop across lower 2μF,i.e.,

HC Verma Test: Electrostatic Potential & Capacitance - Question 16

In the circuit shown in figure charge stored in the capacitor of capacity 5μf is

HC Verma Test: Electrostatic Potential & Capacitance - Question 17

Plate A of a parallel air filled capacitor is connected to a spring having force constant k and plate B is fixed. If a charge +q is placed on plate A and charge _q on plate B then find out extension in spring in equilibrim. Assume area of plate is `A'

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 17


At equilibrium,
Felectric=Fspring
qE=kx ____(1)
we know that,
C=Q/V
And V=ε.d
C=Aε0/d
Therefore, ε=θ/Aε0
Here, ε=q/ Aε0
Putting the value in the equation (1)
q/ Aε0=kx
x=q2/akε0

HC Verma Test: Electrostatic Potential & Capacitance - Question 18

Three uncharged capacitors of capacitane C1 = 1mF, C2 = 2mF and C3 = 3mF are connected as shown in figure to one another and to points A, B and D potential fA = 10V, fB = 25V and fD = 20 V, Determine the potential (f0) at point O.

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 18

⇒q1​+q2​+q3​=0
⇒C1​(Vo​−VA​)+C2​(Vo​−VB​)+C3​(Vo​−VD​)=0
⇒(C1​+C2​+C3​)Vo​=C1​VA​+C2​VB​+C3​VD
Vo​= C1​VA​+C2​VB​+C3​VD​​/ C1​+C2​+C3
= [(1×10)+(2×25)+(3×20)​]/(1+2+3)
=(10+50+60)/6
​=20Volts

 

HC Verma Test: Electrostatic Potential & Capacitance - Question 19

Five capacitors are connected as shown in the figure. Initially S is opened and all capacitors are uncharged. When S is closed, steady state is obtained. Then find out potential difference between the points M and N.

  

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 19

Five capacitors 4μF, 2μF, 4μF, 6μF and 1.2μF are connected as shown in the figure.
Here, Equivalent capacitance = ½,
EMF = 24
Thus, charge passes through each capacitor = 12 μC
Voltage across 4μF = 3V
Voltage across 6μF = 2V
=> Potential difference (V):
V = 3 + 7+ 2 = 12V
Thus, potential difference (V) between the two given points M and N is 12v.
 

HC Verma Test: Electrostatic Potential & Capacitance - Question 20

Find the potential difference Va - Vb between the points a and b shows in each parts of the figure.

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 20

a.In this figure, the left and the right branch is symmetry. So the current go to the branch 'ab' for both sides are opposite and equal. Hence it cancels out.
Thus, net charge, Q= 0. ∴V=Q/C​=0/C​=0
∴Vab​=0
b.The net potential, V= Net charge /Net capacitance ​=C1​V1​+C2​V2​+C3​V3/7​​
V=(24+24+24​)/7=72/7​=10.28V 

HC Verma Test: Electrostatic Potential & Capacitance - Question 21

Each plate of a parallel plate air capacitor has an area S. What amount of work has to be performed to slowly increase the distance between the plates from x1 to x2 If the charge of the capacitor, which is equal to q or

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 21

Given,
Area of plate-S
Initial distance=X1
Final distance=X2
Charge given, q
Initial capacitance
C1=Sε/ X1
Energy stored
V1=q2/2C=q2/2(Sε/X1)
U1= q2X1/2Sε
Final capacitance
C2= Sε/X2
Energy stored,
U2= q2 x2/2Sε
Amount of work done=Change in stored energy between capacitor
=Uf-Ui=U2-U1
=(q2X2/2Sε)- (q2X1/2Sε)
Work done=q2/2Sε (X2-X1)

HC Verma Test: Electrostatic Potential & Capacitance - Question 22

Each plate of a parallel plate air capacitor has an area S. What amount of work has to be performed to slowly increase the distance between the plates from x1 to x2 If the voltage across the capacitor, which is equal to V, is kept constant in the process.

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 22

When voltage is kept const., the force acing on each plate of capacitor will depend on the distance between the plates. 
From energy conversion,
Uf-Ui=Acell+Aagent
Or,(1/2)(ε0S/x2)V2-(1/2)(ε0S/x1)V2
=[(ε0S/x2)- (ε0S/x1)] V2 +Aagent
(as Acell=(qf-q1)V=(Cf-Ci)V2)
So, Aagent= (ε0SV2/2)[(1/x1)-)1/x2)]

HC Verma Test: Electrostatic Potential & Capacitance - Question 23

If charge on left plane of the 5F capacitor in the circuit segment shown in the figure is-20C, the charge on the right plate of 3F capacitor is

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 23

If the charge on left plate of 5μF is −20μC, then the charge on right plate of 5μF is +20μC
So due to the polarization the charge on the left plate of 3μF is negative and the charge on the right plate of 3μF is positive.
thus,  charge on right plate of 3μF is Q=[3/(3+4)]×20=60/7​=8.57μC

HC Verma Test: Electrostatic Potential & Capacitance - Question 24

In the circuit shown, the energy stored in 1μF capacitor is

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 24

The capacitance 4 and (3,5,1) are in parallel so potential across (3,5,1) will be V=24V.
The equivalent capacitance of (3,5,1) is Ceq​=3(5+1)/{3+(5+1)}​=2μF
and Qeq​=Ceq​V=2×24=48μC
As 3 and (5,1) are in series so charge on 3 and (5,1) is equal to Qeq​.
Thus potential across (5,1) is V51​= Qeq​​/C51​=48/(5+1)​=8V
As 5 and 1 are in parallel so potential difference of capacitors will be same i.e 8V
Now energy stored in 1 is =(1/2)​C1​V512​=(1/2)​×10−6×82=32μJ

HC Verma Test: Electrostatic Potential & Capacitance - Question 25

A capacitor C1 = 4mF is connected in series with another capacitor C2 = 1mF. The combination is connected across a d.c. source of voltage 200V. The ratio of potential across C1 and C2 is

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 25

Voltage in series connections are,
V1=C2/{(C1+C2) x V}  V2={C1/(C1+C2)xV}]
V1=(1/S) x 200
V2=(4/S) x200
Ration, V1/V2=((1/S) x200)/((4/S)x200)=1:4

HC Verma Test: Electrostatic Potential & Capacitance - Question 26

A 5.0 mF capacitor having a charge of 20 mC is discharged through a wire of resistance of 5.0 W. Find the heat dissipated in the wire between 25 to 50 ms after the capactions are made.

HC Verma Test: Electrostatic Potential & Capacitance - Question 27

A charged capacitor is allowed to discharge through a resistance 2Ω by closing the switch S at the instant t = 0. At time t = ln2μs, the reading of the ammeter falls half of its initial value. The resistance of the ammeter equal to

HC Verma Test: Electrostatic Potential & Capacitance - Question 28

A capacitor C =100μF is connected to three resistor each of resistance 1 kW and a battery of emf 9V. The switch S has been closed for long time so as to charge the capacitor. When switch S is opened, the capacitor. Discharges with time constant

HC Verma Test: Electrostatic Potential & Capacitance - Question 29

In the transient shown the time constant of the circuit is :

Detailed Solution for HC Verma Test: Electrostatic Potential & Capacitance - Question 29

Applying Thevenin's theorem we consider the circuit from right side and short circuiting the voltage sources and opening the extreme right resistance we get the equivalent resistance
=1/Rth​​=(1/3R)​+(1/R)​=4/3R=3R/4​ Rth​=Thevenin’s resistance
So now adding the remaining resistance R with Rth​ in series we get the equivalent resistance 
Req​=(3R/4)​+R=7R/4​
And time constant τ=RC
τ=(7/4)​RC

HC Verma Test: Electrostatic Potential & Capacitance - Question 30

In the circuit shown in figure C1 =2C2 . Switch S is closed at time t=0. Let i1 and i2 be the currents flowing through C1 and C2 at any time t, then the ratio i1 / i2

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