Video Lecture

Theory For Making Notes

Potentiometer

A potentiometer is an instrument which allows the measurement of potential difference without drawing any current from the circuit being measured. Hence, it acts as an infinite-resistance voltmeter.

The resistance between A and B is a uniform wire of length L, with a sliding contact C at a distance x and B. The potential difference V is measured by sliding the contact until the galvanometer G reads zero. The no-deflection condition of the galvanometer ensures that there is no current through the branch containing G and the potential difference to be measured. The length x for no-deflection is called as the balancing length.

If l is the resistance per unit length of the wire AB, under balanced condition (i.e., when no current is indicated by galvanometer G), the pd to be measured is given as

\displaystyle V={{V}_{{CB}}}={{V}_{{AB}}}\frac{{{{R}_{{CB}}}}}{{{{R}_{{AB}}}}}={{V}_{{AB}}}\frac{{\lambda \left( x \right)}}{{\lambda L}}

= \left( {\frac{{{{V}_{{\text{AB}}}}}}{L}} \right)\times x

The ratio VAB/L  is called the potential gradient in the wire AB.

 

Comparing Two Cells using Potentiometer

A potentiometer is commonly used for comparison of emfs of cells. A battery X is connected across a long uniform wire AB. The cells E1 and E2 (whose emfs are to be compared) are connected as shown along with a galvanometer.

First the key S1 is pressed which brings E1 in the circuit. The sliding contact C is moved till the galvanometer shows no deflection. Let the length AC = L1. Next S1 is opened and S2 is closed. This brings E2 in the circuit. Let C’ be the new null point and let AC’ = L2. Then, clearly,

\displaystyle \frac{{{{E}_{1}}}}{{{{E}_{2}}}}=\frac{{{{L}_{1}}}}{{{{L}_{2}}}}

Measurement of Internal Resistance of a Cell

A potentiometer can be used to find the internal resistance of a cell. First the emfE of the cell is balanced against a length AC = L. A known resistance R is then connected across the cell as shown. The terminal voltage V is now balanced against a smaller length AC’ = L’

 

Then,     \displaystyle \frac{E}{V}=\frac{L}{{{L}’}}

But we know that     \displaystyle \frac{E}{V}=\frac{{R+r}}{R}

 

\displaystyle \frac{{R+r}}{R}=\frac{L}{{{L}’}}

 

\displaystyle r=\left( {\frac{L}{{{L}’}}-1} \right)R

 

Illustration

A battery of emf 4 V is connected across a 10 m long potentiometer wire having a resistance per unit length 1.6 W m–1. A cell of emf 2.4 V is connected so that its negative terminal is connected to the low potential end of the potentiometer wire and the other end is connected through a galvanometer to a sliding contact along the wire. It is found that the no-deflection point occurs against the balancing length of 8 m. Calculate the internal resistance of the 4 V battery.

Solution

 

emf of cell   = (potential gradient) X (balancing length)

 

\displaystyle {{E}_{1}}=\frac{{{{V}_{{AB}}}}}{L}\times x

 

or         \displaystyle 2.4=\frac{{{{V}_{{AB}}}}}{{10}}\times 8      

 

⇒ VAB = 3 V

 

Consider the loop containing E. Applying potential divider concept,

 

\displaystyle {{V}_{{AB}}}=E\frac{{{{R}_{{AB}}}}}{{{{R}_{{AB}}}+r}}

 

      \displaystyle 3=4\frac{{1.6\times 10}}{{1.6\times 10+r}}

 

⇒   r = 16/3 Ω

 

Note that as there is no current through the cell and galvanometer, the battery E, the internal resistance r and the potentiometer wire AB are in series.

Practice Questions (Level-1)

Q.1

In an experiment to measure the internal resistance of a cell by a potentiometer, it is found that the balance point is at a length of 2 m, when the cell is shunted by a 5W resistance and at a length of 3 m, when the cell is shunted by a 10 W resistance. The internal resistance of the cell is

(a)   1.5 W              (b)   10 W                   (c)   15 W           (d)   1 W

Ans :   (b)

Q.2

A resistance of 4W and a wire of length 5 metres and resistance 5W are joined in series and connected to a cell of e.m.f. 10V and internal resistance 1W. A parallel combination of two identical cells is balanced across 300 cm of the wire. The e.m.f. of each cell is  

(a)    1.5 V

(b)    3.0 V                                              

(c)    0.67 V                                           

(d)    1.33 V

Ans.  (b)

Practice Questions (Level-2)

Q.1

If the length of the potentiometer wire is decreased, then its sensitivity :  

(a) Increases           

(b) Decreases          

(c) Remains unaffected         

(d) Either (b) or (c)

Ans:   (b)

Q.2

In an experiment to measure the internal resistance of a cell by a potentiometer it is found that all the balance points at a length of 2 mtr. When the cell is shunted by a 5 ohm resistance, and is at a length of 3 m when the cell is shunted by a 10 ohm resistance, the internal resistance of the cell is then :  

(a)    1.5 \displaystyle \Omega  

(b)    10 \displaystyle \Omega   

(c)    15 \displaystyle \Omega   

(d)    1 \displaystyle \Omega

Ans:   (b)

Q.3

A 10 m long wire of resistance 20 \displaystyle \Omega is connected in series with a battery of e.m.f. 3 V (negligible internal resistance) and a resistance of 10 \displaystyle \Omega . The potential gradient along the wire in volt per metre is :         

(a)    0.02            (b)     0.1              (c)     0.2               (d)     1.2

Ans:  (c)

Q.4

In a potentiometer experiment the balancing point with a cell is at length 240 cm. On shunting the cell with a resistance of 2 \displaystyle \Omega the balancing length becomes 120 cm.  The internal resistance of the cell is :         

(a)    1 \displaystyle \Omega

(b)    0.5 \displaystyle \Omega  

(c)    4 \displaystyle \Omega     

(d)    2 \displaystyle \Omega

Ans:   (d)

Q.5

In the above question if the jockey touches the wire at a distance of 560 cm from A, what will be the current in the galvanometer ?

(a) \displaystyle \frac{{3E}}{{22r}}              

(b) \displaystyle \frac{{13E}}{{22r}}                     

(c) \displaystyle \frac{{5E}}{{22r}}

(d) \displaystyle \frac{{7E}}{{24r}}

Ans :    (a)

Q. 6

Consider the potentiometer circuit arranged as in fig. The potentiometer wire is 600 cm long, and its resistance is 15 r.

At what distance from point A should the jockey touch the wire to get zero deflection in the galvanometer ?

(a) 400cm       

(b) 240 cm           

(c) 320 cm          

(d) 560cm

Ans.  (c)