Q. This 16-part problem illustrates the use of experimental data from bomb calorimetry and other sources, combined with thermodynamic relations derived in this and earlier chapters, to evaluate the standard molar combustion enthalpy of a liquid hydrocarbon. The substance under investigation is n-hexane, and the combustion reaction in the bomb vessel is

C₆H₁₄ (l) + 19/2O₂(g) → 6CO₂(g) + 7H₂O(l)

Assume that the sample is placed in a glass ampoule that shatters at ignition.

States 1 and 2 referred to in this problem are the initial and final states of the isothermal bomb process. The temperature is the reference temperature of 298.15K.

(a) Begin by using the masses of C₆H₁₄ and H₂O placed in the bomb vessel, and their molar masses, to calculate the amounts (moles) of C₆H₁₄ and H₂O present initially in the bomb vessel. Then use the stoichiometry of the combustion reaction to find the amount of O₂ consumed and the amounts of H₂O and CO₂ present in state 2. (There is not enough information at this stage to allow you to find the amount of O₂ present, just the change.) Also find the final mass of H₂O. Assume that oxygen is present in excess and the combustion reaction goes to completion.

(b) From the molar masses and the densities of liquid C₆H₁₄ and H₂O, calculate their molar volumes.

(c) From the amounts present initially in the bomb vessel and the internal volume, find the volumes of liquid C₆H₁₄, liquid H₂O, and gas in state 1 and the volumes of liquid H₂O and gas in state 2. For this calculation, you can neglect the small change in the volume of liquid H₂O due to its vaporization.