Figure shows three spherical and equipotential surfaces A, B and

Previous Year Papers

Download Solved Question Papers Free for Offline Practice and view Solutions Online.

Test Series

Take Zigya Full and Sectional Test Series. Time it out for real assessment and get your results instantly.

Test Yourself

Practice and master your preparation for a specific topic or chapter. Check you scores at the end of the test.
Advertisement

 Multiple Choice QuestionsMultiple Choice Questions

251.

An uncharged sphere of metal is placed inside a charged parallel plate capacitor. The electric lines of force will look like


252.

The electric potential at a point on the axis of an electric dipole depends upon the distance r(>> a) of the point from centre of the dipole as

  • ∝ r

  • ∝ 1r

  • ∝ 1r2

  • ∝ 1r3


Advertisement

253.

Figure shows three spherical and equipotential surfaces A, B and C round a point charge q. The potential difference VA − VB = VB − VC. If t1  and t2  be the distance between them. Then

     

  • t1 = t2

  • t1 > t2

  • t1 < t2

  • t1 ≤ t2


C.

t1 < t2

Potential difference between two equipotential surfaces A and B,        VA - VB = kq 1rA - 1rB                      = kq rB - rArArB                     = kqt1rArBor           t1    = VA - VB rArBkqor             t1   rArBSimilarly, t2  rBrCSince, rA <   rB <  rC, therefore rArB < rBrC             t1 < t2


Advertisement
254.

Three capacitors of capacitances 1 µF, 2 µF and 4 µF are connected first in a series combination, and then in a parallel combination. The ratio of their equivalent capacitances will be

  • 2 : 49

  • 49 : 2

  • 4 : 49

  • 49 : 4


Advertisement
255.

A fully charged capacitor has a capacitance C. It is discharged through a small coil of resistance wire embedded in a thermally insulated block of specific heat capacity s and mass m. If temperature of the block is  raised by ΔT, the potential difference V across the capacitor is

  • ms TC

  • mC Ts

  • 2 mCTs

  • 2 msTC


256.

In the given figure, a hollow spherical capacitor is shown. The electric field will not be zero at

    

  • r < r1

  • r1 < r2

  • r < r2

  • r1 < r < r2


257.

A capacitor of capacitance 5 µF is connected as shown in the figure. The internal resistance of the cell is 0.5 Ω. The amount of charge on the capacitor plates is

  • 80 µC

  • 40 µC

  • 20 µC

  • 10 µC


258.

The potential at a point P which is forming a comer of a square of side 93 mm with charges, Q1 = 33nC, Q2 = − 51 nC, Q3 = 47 nC located at the other three comers is nearly

  • 16 kV

  • 4 kV

  • 400 kV

  • 160 V


Advertisement
259.

Two equal metal balls are charged to 10 and − 20 units of electricity. Then they are brought in contact with each other and then again separated to the original distance. The ratio of magnitudes of the force between the two balls before and after contact is

  • 8 : 1

  • 1 : 8

  • 2 : 1

  • 1 : 2


260.

The electric potential due to a small electric dipole at a large distance r from the centre of the dipole is proportional to

  • r

  • 1r

  • 1r5

  • 1r2


Advertisement