Current `i` is being driven through a cell of emf `epsilon` and internal resistance3 `r`, as shown

(i) the cell absorbs energy at rate of `epsilon i`
(ii) The cell stores chemical energy at the rate of `(epsilon i - i^(2)r)`
(iii) The potential differnece across the cell is `epsilon+ir`
(iv) some heat is produced in the cell

Current I is being driven through a cell of emf E and internal resistance r as shown in the figure. Choose the following correct statements.

A cell of emf epsilon and internal resistance r is charged by a current I, then

Find the potential difference across each cell and the rate of energy dissipated in R

A cell of emf epsilon and internal resistance r drives a current i through an extermal resistance R (i) The cell suppllied epsilon i power (ii) Heat is produced in R at the rate epsilon i (iii) Heat is produced in R at the rate epsilon I ((R )/(R+r)) (iv) Heat is produced in the cell at the rate epsilon i((r ?/(R+r))

A capacitor is conneted to a cell emf E having some internal resistance r . The potential difference across the

A number of indentical cells, n, each of emf epsilon , internal resistance r, connected in series are charged by a d.c. source of emf epsilon' , using a resistor R.(i) Draw the circuit arrangemnet. (ii) Deduce the expression for (a) the charging current and (b) the potential difference across the combination of the cells

A cell of emf epsilon and internal resistance r is connected across a load resistance R (i) Find the maximum power delivered at the load ? (ii) Draw the power (P ) vs load resistance ( R ) graph.

In a arrangement, 3n cells of emf epsilon and internal resistance r are connected in series. Out of 3n cells polarity of n cells is reversed. Current in the circuit is

Two cells of unequal emfs epsilon_1 and epsilon_2 , and internal resistance r_1 and r_2 are joined as shown. V_A and V_B are the potential at A and B respectively. (i) One cell will continuously supply energy to the other (ii) The potential difference across both the cells will be equal (iii) The potential difference across one cell with be greater than its emf. (iv) V_A - V_B = (epsilon_1 r_1 + epsilon_2 r_2)/(r_1 + r_2) .