Lesson

Background

Butane is an organic compound with the formula C₄H₁₀. Very pure forms of butane can be used as refrigerants, for instance in household refrigerators and freezers. Butane is also used as lighter fuel for a common lighter. Butane is a highly flammable, colorless, easily liquefied gas that quickly vaporizes at room temperature and pressure.

In this lab, you will collect a measurable volume of butane gas using water displacement. Using Dalton’s law and the Ideal gas law, the number of moles of butane gas and then the molar mass of butane can be calculated. Your experimental value for molar mass will be compared to the known molar mass of butane and percent error calculated.

Dalton’s Law:      P_total = P_butane  +  P_{water vapor}

Ideal Gas Law:    PV = nRT

Percent error:    |accepted – experimental| x 100%
                                           accepted

Prelab Questions

1. A sample of nitrogen is collected over water at 27 ⁰C. What is the pressure of the nitrogen if the total pressure is 760. mm Hg?
2. A sample of an unknown gas has a mass of 0.25 g, pressure of 770. mm Hg, and a volume of 0.10 L. If the temperature is 25 ⁰C, what is the molar mass of the gas?
3. In step one of the procedures, you are told to submerge the lighter in water before taking its initial mass. Why do you think you are asked to do this?

Objective

Experimentally determine the molar mass of butane.

Materials

• Balance with precision to at least 0.01 gram
• Butane lighter
• Graduated cylinder, 100 mL
• Thermometer
• Large water bucket (room temperature)
• Barometer – Alternate: can use internet to find pressure for the area
• Paper towels

Safety

• Always wear safety goggles when handling chemicals in the lab.
• Wash your hands thoroughly before leaving the lab.
• Follow the teacher’s instructions for cleanup of materials and disposal of chemicals.
• Keep butane away from open flames as it is highly flammable.
• When you release the collected butane at the end of the lab, be sure that you do so in a fume hood or outside.

Procedure

1. Place the lighter under water. Remove the lighter, shake it off and dry the excess water with a paper towel. Using the balance, determine the mass of the lighter and record. 
2. Fill water bucket two-thirds full with room-temperature water.
3. Fill a 100 ml graduated cylinder to the absolute top with water. Place your hand over the top of the graduated cylinder and invert into the bucket underneath the water. Make sure the graduated cylinder has no air in it once it has been inverted.  See Figure 1.
4. One group member should hold the butane lighter under the water while another holds the graduated cylinder above it. The student holding the lighter should depress the plunger on the lighter until at least 90 mL of butane is collected in the graduated cylinder above it. Do not let any butane escape outside of the graduated cylinder. See Figure 1.
5. Place the thermometer in the bucket and record the temperature in ⁰C.
6. Carefully lift the graduated cylinder until the level of butane is level with the water level in the bucket. While maintaining equal water levels, read the exact volume of the butane gas to the nearest 0.1 mL and record. See Figure 2.
7. While keeping it upside down, remove the graduated cylinder with your hand covering the opening and take it to the fume hood or outside to release the collected butane gas safely.
8. Shake off the butane lighter and dry the outside with a paper towel. DO NOT depress the plunger on the lighter! Record the mass of the lighter.
9. Record the barometric pressure using a barometer or look up the current pressure for the area on the internet.

Data

Calculations

Show all work for each of the following calculations.

1. Determine the mass of butane collected.
2. Determine the vapor pressure of water using the chart below.

Temperature of water: ________     Vapor Pressure of water: __________

4. Determine the pressure of the butane gas collected by using Dalton’s law. (Note that P_total = P_atm)
5. Using the ideal gas law (PV = nRT), determine the number of moles of butane gas collected. Make sure you convert your measurements to the appropriate units for the ideal gas constant, R, if they do not match up.
6. Determine the molar mass of butane using your experimental data.
7. Determine the accepted value for the molar mass of butane, C₄H₁₀, from the molar masses on the periodic table, and use this to calculate the percent error of your experimental results.

Analysis

1. Butane gas doesn’t dissolve very well in water. Why is this necessary to perform this experiment?
2. How could this procedure be used to identify an unknown gas?
3. Identify at least 2 possible sources of error and how they could have affected your results.

Conclusion

Write a paragraph to explain how you determined the molar mass of butane. Explain possible sources of error and how you could adjust your technique or the materials or procedures to minimize those sources of error if you were to repeat the experiment.