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A negatively charged oil drop is prevented from falling under gravity by applying a vertical electric field 100 Vm^-1. If the mass of the drop is 1.6 x 10^-3 g, the number of electrons carried by the drop is (g = 10 ms^-2)

10¹⁸
10¹⁵
10¹²
10⁹

42.

Which one of the following graphs represents the variation of electric field with distance r from the centre of a charged spherical conductor of radius R?

43.

Two conducting spheres A and B of radius a and b respectively are at the same potential. The ratio of the surface charge densities of A and B is

$\frac{b}{a}$
$\frac{a}{b}$
$\frac{a^{2}}{b^{2}}$
$\frac{b^{2}}{a^{2}}$

44.

Three charges 2q, -q, -q are located at the vertices of an equilateral triangle. At the circumcentre of the triangle

the field is zero but potential is non-zero
potential is zero and the field is infinity
the field is non-zero but potential is zero
both the field and potential are non-zero

45.

Millikan's oil-drop experiment established that

electric charge depends on velocity
specific charge of electron is 1.76 x 10¹¹ Ckg^-1
electron has wave nature
electric charge is quantized

46.
Two identical conducting spheres carrying different charges attract each other with a force F when placed in air medium at a distance d apart. The spheres are brought into contact and then taken to their original positions. Now the two spheres repel each other with a force whose magnitude is equal to that of the initial attractive force.The ratio between initial charges on the spheres is

$- (3 + \sqrt{8}) only$

$- 3 + \sqrt{8} only$

$- (3 + \sqrt{8}) or (- 3 + \sqrt{8})$

$+ \sqrt{3}$

$- (3 + \sqrt{8}) or (- 3 + \sqrt{8})$

Since the two charges (spheres) attract, they will be opposite in sign, i,e q₁ and − q₂.

$Force, F = \frac{1}{4 {πε}_{0}} \frac{q_{1} \times - q_{2}}{d^{2}}$

After touching, charge on each will be $\frac{q_{1} - q_{2}}{2}$

New force, $F' = \frac{1}{4 {πε}_{0}} {(\frac{q_{1} - q_{2}}{2})}^{2} \times \frac{1}{d^{2}}$

Given, $|F| = |F'|$

On solving by quadratic equations, we get

$\frac{q_{1}}{q_{2}} = - (3 + \sqrt{8}) or (- 3 + \sqrt{8})$

47.

Small drops of the same size are charged to V volt each. If n such drops coalesce to form a single large drop, its potential will be

Vn
V/n
Vn^1/3
Vn^2/3

48.

An electric dipole of length 1 cm is placed with the axis making an angle of 30° to an electric field of strength 10⁴ NC^-1. If it experiences a torque of $10 \sqrt{2} Nm$ Nm, the potential energy of the dipole is

0.245 J
2.45 × 10^-4 J
24.5 × 10^-4 J
245.0 J

49.

Charges + 2q, + q and + q are placed at the comers A, B and C of an equilateral triangle ABC. If E is the electric field at the circumcentre 0 of the triangle, due to the charge + q, then the magnitude and direction of the resultant electric field at O is