NEET Physics Current Electricity MCQs

Two wires of the same material and length but different cross-sectional areas are connected in series across a battery. If the ratio of their radii is 2:1, what is the ratio of the power dissipated in them?

Two identical resistors are connected in series across a battery. If one of the resistors is now short-circuited, the power dissipated in the other resistor will:

A conductor of cross-sectional area $1 imes 10^{-6} m^2$ carries a current of 4A. If the number density of free electrons is $10^{28} m^{-3}$, and the charge on an electron is $1.6 imes 10^{-19} C$, what is the magnitude of the drift velocity of the electrons, assuming they all contribute to the current?

A cylindrical copper conductor with radius $r_1$ carries a current $I$. If the radius is doubled to $2r_1$ while keeping the current the same, and assuming the electric field within the conductor remains uniform, how does the drift velocity of electrons change?

In a Wheatstone bridge with resistances $R_1$, $R_2$, $R_3$, and $R_x$, the galvanometer shows null deflection. If a shunt resistance $S$ is connected parallel to $R_3$, what is the equivalent resistance that replaces $R_3$ in the balanced condition?

Two potentiometers, P1 and P2, have identical wires and driver cells. However, P1 uses a rheostat with a higher resistance range than P2. Which potentiometer will offer greater sensitivity in balancing a given cell?

A potentiometer wire of length L and resistance R is connected to a driver cell of negligible internal resistance and emf E. A cell of emf E/2 is balanced at a length L/2. If the length of the potentiometer wire is doubled, at what length will the same cell be balanced?

A potentiometer is being used to compare two cells of emfs $E_1$ and $E_2$. The balancing lengths are found to be $l_1$ and $l_2$ respectively. If a resistance R is connected across $E_2$, its balancing length changes to $l_3$. Which of the following relations must hold true?

A cell of emf E and internal resistance r is connected across a variable external resistance R. The graph of terminal potential difference V against current I reaches a maximum value of V. What is the relationship between E, r, and this maximum value of V?

n identical cells, each of emf E and internal resistance r, are connected in series to form a closed circuit. If one cell is reversed, what is the current in the circuit?