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Experiment: Joule’s Law of Heating

PRELIMINARY Questions

1) A THERMALLY ISOLATED CONTAINER HOLDS 50 ML WATER. A 5 W RESISTOR, CONNECTED TO A 10 V POWER SUPPLY, IS PLACED INTO THE WATER AND THE CIRCUIT IS TURNED ON FOR 5 MINUTES. DURING THIS TIME HEAT GENERATED BY THE RESISTOR IS ABSORBED BY THE WATER, WHICH HEATS UP FROM AN INITIAL TEMPERATURE OF 20 OC TO A FINAL TEMPERATURE OF 48.7OC.

a) What is the rate of energy (i.e. power) dissipated through the resistor, in Joules per second?

b) How much energy is dissipated during the 5 minute interval?

c) The specific heat capacity of water, c, is 1.000 calories/goC . How many calories of heat are absorbed by the water during this experiment?

d) If no energy is lost to the container or outside environment, the energy dissipated (lost) by the circuit is equal to the energy gained by the water. Both of these values were calculated above. Based on the results of your calculations, what is the relationship between electrical energy in Joules and heat energy.

introduction

WHEN AN ELECTRIC CURRENT FLOWS THROUGH A RESISTANCE ENERGY IS EXPENDED (I.E. WORK IS REQUIRED TO DRIVE CHARGE THROUGH THE RESISTOR). POTENTIAL DIFFERENCE IS DEFINED AS THE WORK PER UNIT CHARGE REQUIRED TO MOVE A CHARGE FROM ONE POINT TO ANOTHER. SYMBOLICALLY,

DV = W/q (1)

where DV is potential difference (also known as the voltage or electromotive force), W the work done, and q the quantity of charge transported. The unit of potential difference is the volt, which is the potential difference such that 1 joule of work is used to move 1 coulomb of charge (or 1 volt = 1 J/C).

Quantity of charge, q, is the product of the intensity of the current (I) and the time (t) the current flows. For a steady current,

q = It (2)

The energy expended in an electric circuit can be written as,

W = DVq = DVIt = I2Rt (in joules) (3)

Recall from last term that the heat (Q) absorbed by a substance is related to the mass of the substance (m), the specific heat capacity of the substance (c), and the change in temperature of the substance (DT) according to the relation,

Q = cmDT (in calories) (4)

where Q is in calories, c is in cal/goC, m is in g, and DT is in oC. When immersed in a volume of water, the energy expended in a circuit, which is released as heat, is related to the heat absorbed by the liquid. For water, recall the specific heat capacity is 1.00 cal/g oC. The relationship between heat absorbed by the water and the energy expelled by the circuit is

W = JQ (5)

where J is called Joule’s constant. Experiments have determined the value of J to be approximately 4.18 J/cal. Rearranging equation (5),

Q = W/J = I2Rt/J (6)

Combining equations (4) and (6) then rearranging terms,

cmDT = I2Rt/J (7)

or

DT = (R.t/c.m.J).I2 (8)

In this experiment, we are going to use this relationship to determine Joule’s constant.

in calories. This value is known as Joule’s constant.

objectives

· TO STUDY THE HEATING EFFECT DUE TO AN ELECTRIC CURRENT

· To determine Joule’s constant (J) using an electrocalorimeter

MATERIALS

|POWER MACINTOSH OR WINDOWS PC |WIRES |

|UNIVERSAL LAB INTERFACE |CLIPS TO HOLD WIRES |

|LOGGER PRO |ADJUSTABLE |

|VERNIER CURRENT AND VOLTAGE PROBE |ELECTRIC CALORIMETER |

|ADJUSTABLE 5-VOLT DC POWER SUPPLY |VERNIER TEMPERATURE PROBE |

[pic]

Figure 1

Experimental SEtup

1. PREPARE THE COMPUTER FOR DATA COLLECTION BY OPENING “EXP 25” FROM THE PHYSICS WITH COMPUTERS EXPERIMENT FILES OF LOGGER PRO. THE METER WINDOW SHOULD DISPLAY POTENTIAL AND CURRENT READINGS.

2. Connect DIN 1 on the Dual Channel Amplifier to DIN 1 on the Universal Lab Interface. Connect DIN 2 to DIN 2. Connect a Voltage Probe to PROBE 1 on the Dual Channel Amplifier. Connect a Current Probe to PROBE 2.

3. With the power supply turned off, connect the power supply, electric calorimeter, wires, and clips as shown in Figure 1. Take care that the positive lead from the power supply and the red terminal from the Current & Voltage Probe are connected as shown in Figure 1. Note: Attach the red connectors electrically closer to the positive side of the power supply.

4. Select Zero from the Experiment dropdown box. A dialog box will appear. Select “Zero Potential” then “Zero Current”. This sets the zero for both probes with no current flowing and with no voltage applied.

5. Have your instructor check the arrangement of the wires before proceeding. Turn the control on the DC power supply to 0 V and then turn on the power supply. Slowly increase the voltage to 2.5 V. Record the current and potential values. Calculate the resistance of the electric calorimeter using the relationship

R = V/I

6. Connect the temperature probe to DIN 3 and update the sensor settings for DIN 3 in the Set-Up menu. Add the temperature reading to the meter window.

PROCEDURE

1. RECORD THE VALUE OF THE RESISTOR IN THE DATA TABLE.

2. Place a known mass (volume) of water into the electric calorimeter. Using the thermometer, measure the initial temperature of the water.

3. With the circuit disconnected, set the power supply to 5 V and the rheostat to near its lowest setting.

4. Connect the circuit and let run for 5 min. During the run, record the current and potential difference across the calorimeter (these values should stay fairly constant!). Stir occasionally to insure good heat transfer between the water and the coil.

5. At the end of the 5 minutes, disconnect the circuit and record the final temperature of the water. Be sure to wait until the water reaches its peak temperature.

6. Replace the water with fresh water. Change the setting of the rheostat and repeat steps 2-5.

7. Repeat process for a total of 5 trials.

DATA TABLE

|SET-UP ( |DV = _____V |I = _____A |R = ( | | |

|TRIAL # |MASS OF WATER |Current |Initial Temp. |Final Temp. |DT |

| |(g) |(A) |(oC) |(oC) | |

|1 | | | | | |

|2 | | | | | |

|3 | | | | | |

|4 | | | | | |

|5 | | | | | |

ANALYSIS

1. USING GRAPHICAL ANALYSIS, CREATE A PLOT OF DT VS I2 FOR YOUR DATA POINTS. IS THE DATA LINEAR?

2. Generate a best-fit line for your graph. The slope of the line is ____________.

3. Using equation (8), calculate Joule’s Constant, J, from the slope of the graph.

4. Compare your value for J with the accepted value. What is the % error?

5. What is the significance of the value of J?

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