In the figure shown, battery `1` has emf`=6V` and internal resistance `= 1Omega.` Battery `2` has emf`=2V` and internal resistance `=3Omega.` The wires have negligible resistance. What is the potential difference across the teminals of battery `2`?

A car battery with a 12V e.m.f. and an internal resistance of 0.04 Omega is being charged with a current of 50A. The potential difference V across the terminals of the battery are:

A cell E_1 of emf 6V and internal resistance 2 Omega is connected with another cell E_2 of emf 4V and internal resistance 8 Omega (as shown in the figure). The potential difference across points X and Y is :

A shortage battey with an emf of 10V and an internal resistance 1Omega is connected across an extenal resistance R and liberates of 9W power. Find the potential difference across the teminals of the battery and the value or values of R.

A battery having e.m.f. 5 V and internal resistance 0.5 Omega is connected with a resistance of 4.5 Omega then the voltage at the terminals of battery is

A battery of emf 2V and internal resistance 0.5(Omega) is connected across a resistance in 1 second?

In Fig. 27-51. battery 1 has emf epsi_(1)= 12.0 V and internal resistance r_1= 0.025 Omega and battery 2 has emf_(2)= 12.0 V and internal resistance r_2= 0.012Omega . The batteries are connected in series with an external resistance R. (a) What R value makes the terminal-to-terminal potential difference of one of the batteries zero? (b) Which battery is that?

A battery of six cells each of e.m.f . 2V and internal resistance 0.5Omega is being charged by D.C. mains of e.m.f. 220V by using an external resistance of 10Omega . What is the potential difference across the battery?

A car battery of emf 12V and internal resistance 0.05 omega receives a current of 60 A from an external source, then the terminal potential difference of the battery is