In a network as shown in the figure , the potential difference across the resistance 2 R is (the cell has emf E - volt and no internal resistance )

In the L-R circuit as shown in figure, potential difference across the resistance at some instant is 4 V. Then

Assertion:- To cells of unequal emf E_(1) and E_(2) having internal resistances r_(1) and r_(3) are connected as shown in figure. Then the potential difference across any cell cannot be zero. Reason:- If two cells having nonzero internal resistance and unequal emf are connected across each other as shown, then the current in the circuit cannot be zero.

In the given circuit, if the potential difference across the internal resistance r_1 is equal to E, then the resistance R is equal to:

In the situation shown , the potential difference across the cell of smaller e.m.f is .

In the electrical network shown in the figure, What will be the potential difference (in volt) across 3Omega resistance ?

In the circuit shown in figure potential differences across 6Omega resistance is 4 volt. Find V and i values across each resistance. Also find emf E of the applied battery.

For a cell, a graph is plotted between the potential difference V across the terminals of the cell and the current I drawn the cell. The emf and the internal resistance of the cell are E and r, respectively. Then

In the situation shown , The potential difference across the cell of smaller e.m.f. is

The e.m.f. of a cell is 6 volt. When 2 ampere current is drawn from it then th e potential difference across its terminal remains 3 volt. Its internal resistance.

According to this diagram , the potential difference across the terminals is ( internal resistance of cell =r)