Experiment to convert a galvanometer into a 0–3V voltmeter and study how thermistor resistance changes with temperature using a slide wire bridge.
Apparatus
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Thermistor
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Test tube
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Thermometer
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Slide wire bridge
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Resistance box
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Galvanometer
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Rheostat
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Cell
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Tapping key
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Connecting wires
Theory
A thermistor is a heat-sensitive resistor made from semiconductor materials. Most thermistors have a negative temperature coefficient of resistance (NTC). This means their resistance decreases as temperature rises and increases as temperature falls.
The temperature coefficient of resistance (α) of a wire is the fraction of its resistance at 0°C by which it changes per degree Celsius:
α=Rt−R0R0torRt=R0(1+αt)\alpha = \frac{R_t – R_0}{R_0 t} \quad \text{or} \quad R_t = R_0 (1 + \alpha t)
Where:
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R0R_0 = resistance at 0°C
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RtR_t = resistance at t°C
You can determine α by measuring the resistance at two temperatures, t₁ and t₂:
R1=R0(1+αt1),R2=R0(1+αt2)R_1 = R_0 (1 + \alpha t_1), \quad R_2 = R_0 (1 + \alpha t_2)
Then, dividing these equations gives:
α=R2−R1R1(t2−t1)\alpha = \frac{R_2 – R_1}{R_1 (t_2 – t_1)}
The slide wire bridge allows you to measure the resistance of the thermistor at different temperatures, as described in Experiment No. 1.
Procedure
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Clean the ends of all connecting wires with sandpaper.
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Arrange the apparatus as shown in Figure (a). Connect the battery (B), tapping key (K), and galvanometer (G). Connect one terminal of the galvanometer to point D and the other to a jockey that can touch the slide wire at any point.
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Insert the resistance box in the gap LN and the thermistor in the gap MT. Place the thermistor in a test tube, which you submerge in a beaker of water. Measure the water temperature using the thermometer.
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Wait about 5 minutes for the thermometer in the test tube to reach the water temperature. Record the resistance RthR_{th} of the thermistor.
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Heat the water gradually and stir continuously. Increase the water temperature in steps of 10°C, allowing it to stabilize for 5 minutes at each step. Record the resistance of the thermistor at each temperature.
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Take at least five to six readings until the water boils.
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Plot a graph of RthR_{th} versus temperature tt, with resistance on the y-axis. The graph will not be perfectly straight.
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Select two nearby readings R1R_1 and R2R_2 at temperatures t1t_1 and t2t_2. Calculate the temperature coefficient of resistance using the formula above.
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Repeat for at least three different temperature ranges.
Observations & Calculations
| Temperature (°C) | Thermistor Resistance RthR_{th} (Ω) |
|---|---|
| t₁ | R₁ |
| t₂ | R₂ |
| … | … |
Temperature coefficient of resistance (α):
α=R2−R1R1(t2−t1)\alpha = \frac{R_2 – R_1}{R_1 (t_2 – t_1)}
Precautions
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Ensure the test tube does not touch the sides or bottom of the beaker.
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Take readings only after the thermometer shows a stable temperature.
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Follow all precautions mentioned in Experiment No. 1.
Viva Questions
Q1. What is resistance?
A: Resistance is the property that opposes current flow. It equals the ratio of potential difference to current.
Q2. On what factors does wire resistance depend?
A: Length, cross-sectional area, material, and temperature.
Q3. Define the temperature coefficient of resistance.
A: The fractional change in resistance per degree Celsius rise in temperature.
Q4. Why is the experimental graph not perfectly straight?
A: External and self-heating effects alter the thermistor’s resistance. Only the surrounding temperature is measured by the thermometer.
Q5. What is a thermistor?
A: A temperature-dependent resistor made from semiconductor material, often with a negative temperature coefficient.