Induced Electric Fields MCQ Quiz in தமிழ் - Objective Question with Answer for Induced Electric Fields - இலவச PDF ஐப் பதிவிறக்கவும்

Calculation: 

At t = 10 sec complete loop is in magnetic field therefore no change in flux

e = \(\frac{\mathrm{d} \phi}{\mathrm{dt}}\) = 0

e = 0 for a complete loop 

∴ The value of induced emf in the loop at t = 10 s will be zero

Concept: 

For finding the magnitude of the magnetic moment of the electric field we should know how it varies with distance. 

We should check whether it is a monopole moment, dipole, or quadrupole moment.

First, we have to check its monopole moment which is known as sum of total charges i.e. m = ∑ Q_i 

where Q = charge placed 

If the monopole moment is zero then the system is independent on considering the frame of the origin or we can consider our origin at any point to make our calculation easier.

Electric dipole moment is = P = ∑ p_i = ∑ q.dx = charge × distance

If it is zero then we have to test its quadrupole moment for the electric field. 

Calculation:

Given:  two charges +q and -q placed at distance L.  

Electric monopole moment is = m = -q +q = 0

Here electric monopole moment becomes zero so we have to calculate its electric dipole moment.

We are free to consider origin anywhere because the monopole moment is zero.

Electric dipole moment is = P = charge × distance (with directions)

The electric field is towards for negative charge and away from the positive charge.

Dipole moment = P = q(L/2) (î) + (-q)(L/2)(-î) = qL (î)

so here, the dipole moment is non-zero. we know that for dipole moment electric field varies as E ∝ 1/R³ 

Hence Option 3) is correct.

Calculation:

Given that:

Velocity = 12 cm/sec = 0.12 m/sec

Length of Rod = 15 cm = 0.15 m

B = 0.5 T.

Resistance R = 180 mΩ =  0.18 Ω 

To calculate the power dissipated as heat, we need to first calculate the current flowing.

Since the induced emf is calculated as 

E = BVL

= 0.5 × 0.12 × 0.15

= 9 × 10^-3 Volts.

The current I would be equal to 

I = E/R

I = 9 × 10-3/(0.18)

= 50 × 10^-3 A

The power dissipation is equal to 

P = I²R

= (50 × 10-3 )² × 0.18

P = 4.5 × 10^-4 Watt 

The correct answer is option (4)

Explanation:

Power dissipation is given by the formula E²/R

Induced emf is given as 

E = BVL

Given that:

B = 0.5 T

V = 12 cm/s = 0.12 m/s

L = 15 cm = 0.15 m.

R = 180 mΩ = 0.18 Ω

Calculating E

E = 0.5 × 0.12 × 0.15 

= 9 × 10^-3 Volts

Power P = E2/R

= (9 × 10-3)²/0.18

= 4.5 × 10-4 W

The correct answer is option (3)