According to the ideal gas law for a given pressure, temperature, and volume, the number of moles of gas in that volume is always the same. In this lab, you will use that relationship to calculate the molar mass of an unknown liquid. You will immerse a Dumas tube containing the unknown liquid in boiling water to vaporize the solvent. After waiting a few minutes for the vapor to equilibrate with its surroundings, you will let the vapor condense and then measure the mass of the liquid in the tube. Molar mass doesn't change with phase, so the mass of the condensed liquid is the same as the mass of the vapor.
The unknown liquids are volatile, toxic, and may be flammable, so you will work in a fume hood. Your instructor will dispense your assigned unknown into your Dumas tube for you. Always keep the Dumas tube pointed away from yourself and others. This section of the lab uses a Bunsen burner to boil water. Take care to keep your sleeves, hair, and the unknown liquid away from the flame and use caution when working around hot liquids, glass, and metal.
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Before starting the lab, put on a lab coat, safety glasses, and two pairs of nitrile gloves. Note: Acetone and the unknown liquids rapidly permeate nitrile gloves, so get new gloves if you touch any of these liquids. Let the old gloves dry in the hood before throwing them out.
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Connect one end of a piece of latex tubing to the barbed inlet of a Bunsen burner. Connect the other end of the tubing to the gas jet in your hood. Confirm that the collar at the base of the Bunsen burner is closed.
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With the Bunsen burner on the base of the lab stand, fit a ring fixture onto the lab stand over the Bunsen burner and adjust the rings so that it is centered 2 inches above the flame. Tighten the clamp to fix the ring in position. Place a square of wire gauze on the ring to make a platform.
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Then, clamp a 500-mL Erlenmeyer flask on the platform with a 3-prong clamp. Fix a thermometer clamp above the three-prong clamp and rotated away from the flask.
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Once the clamps are in position, remove the Erlenmeyer flask. Place several boiling chips in the flask and fill it to the 500 mL mark with deionized water.
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Fill a 400-mL beaker with deionized water. Clamp the filled flask back in place on the wire platform.
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Obtain several paper towels. Tear one paper towel into strips about as wide as the length of the elongated neck of the Dumas tube. Note: Move the paper towels out of the way before you light the Bunsen burner.
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Ensure that your fire striker is within easy reach. Then, open the gas jet, hold the striking end close to the top of the Bunsen burner, and rapidly squeeze the movable handle to strike a spark, which will ignite the gas.
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Once you have lit the flame, turn the collar at the base of the barrel to increase the airflow, which will make the flame hotter. Turn the gas valve to increase the height of the flame to about 4 – 6 inches. Note: One student must remain at the workstation while the Bunsen burner is in use.
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Place the Dumas tube in a clean 100-mL beaker and bring it to an analytical balance.
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Tare the 250-mL plastic beaker. Use a laboratory wipe to remove traces of dust and oils from the entire surface of the tube.
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Hold the clean tube in a fresh laboratory wipe and carefully transfer it to the plastic beaker. Record the mass of the empty Dumas tube in your lab notebook.
Table 1: Molar Mass of Unknown Liquid
| Trial |
MassDumas Tube + Unknown |
MassEmpty Dumas Tube |
MassUnknown |
| 1 |
|
|
|
| 2 |
|
|
|
| 3 |
|
|
|
| 4 |
|
|
|
| Average MassUnknown |
|
| Standard deviation |
|
| Pressure (hPa) |
|
| Temperature (ºC) |
|
| Temperature (K) |
|
| Masstube filled with water (g) |
|
| Masswater (g) |
|
| Densitywater (g/cm3) |
1 |
| Volumegas (cm3) |
|
| Molesgas (n) |
|
| Molar massunknown (g/mol) |
|
| Percent error (%) |
|
| Theoretical R (hPa·cm3/mol·K) |
8.314 × 104 |
| Calculated R (hPa·cm3/mol·K) |
|
| Difference between theoretical and calculated R |
|
Click Here to download Table 1
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Use a laboratory wipe to transfer the tube back in your 100-mL beaker.
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When your instructor calls you, bring the Dumas tube in the beaker to the designated dispensing hood where your instructor will add a small volume of the unknown to the tube.
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Wrap the neck of the Dumas tube with paper towels to help maintain a constant temperature.
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Once the water in the Erlenmeyer flask boils, secure the Dumas tube in the thermometer clamp. Carefully rotate the clamp so that the tube is lined up with the Erlenmeyer flask neck and slowly lower the clamp until the body of the Dumas tube is fully immersed in the boiling water. Note: Do not touch the flask.
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Once the Dumas tube is in position, fix the thermometer clamp in place and note the time.
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Now, wait for your unknown liquid to vaporize, which should take 3 – 5 minutes. Note: Top off the water in the flask whenever the water level goes down.
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Once you can't see any liquid in the tube, note the time and wait another 3 minutes to let the vapor temperature and pressure equilibrate with its surroundings.
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Raise the thermometer clamp to lift the Dumas tube from the boiling water. Rotate the clamp away from the flask so that the tube can cool in ambient air.
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After 2 – 3 minutes, carefully dry the outside of the tube with paper towels. Note: The drops of water may still be hot.
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Wait for the tube to cool to room temperature so that the vapor fully condenses. Once cooled, remove the tube from the clamp and dry any remaining traces of water on the tube before placing it in the 100-mL beaker. Note: Residual water will add mass.
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Carry the beaker to a balance and clean the outside of the tube with a laboratory wipe. Measure the mass. Record this in your lab notebook as the post-trial one mass.
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Perform three more trials in the same way. To find the mass of the remaining unknown after each trial, subtract the mass of the empty Dumas tube from each post-trial mass.
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When you finish the 4th trial, turn off the gas to extinguish the Bunsen burner. Wait 5 minutes before disassembling the ring, gauze, and Bunsen burner from the ring stand.
