2.7 Calculation of Enthalpy Changes of a Class of Chemical Reactions 93
changes (see Chapter 7). The calculation is more complicated. We will not discuss that
case.EXAMPLE2.32
Find the final temperature if the reaction of Eq. (2.7-1) is carried out adiabatically at constant
pressure beginning at 298.15 K. Assume that a stoichiometric mixture is present before the
reaction and that the reaction proceeds to completion. Assume that the heat capacity of water
vapor is constant and equal to its value at 2000 K.
Solution
The reaction as written in Eq. (2.7-1) includes liquid water as the product. In our case
the water produced will be a vapor, so we calculate∆H◦at 298.15 K for the gaseous
product:∆H◦(298.15 K) 2 ∆fH◦(H 2 O(g))− 0 − 02(− 241 .818 kJ mol−^1 )− 483 .636 kJ mol−^1 −483636 J mol−^1CP(products)2(51.18JK−^1 mol−^1 ) 102 .36JK−^1 mol−^1∫T 2298 .15 K(
102 .36JK−^1 mol−^1)
dT−483636 J mol−^1 0(
102 .36JK−^1 mol−^1)
(T 2 − 298 .15 K)483636 J mol−^1T 2 5023 K≈5000 KThis result might be inaccurate because of the actual dependence of the heat capacity of water
vapor on temperature.Exercise 2.28
Find the final temperature if a stoichiometric mixture of methane and oxygen is ignited at
298.15 K and allowed to react adiabatically at a constant pressure. Assume that the reaction
proceeds to completion and that the heat capacities of the products are constant and equal to their
values at 2000 K.If heat capacities are represented by polynomials as in Table A.6, a more nearly
accurate final temperature can be calculated. This leads to a nonlinear equation, which
can be solved by trial and error or by other numerical techniques.Exercise 2.29
Using the parameters from Table A.6, find the final temperature after the adiabatic combustion
of the stoichiometric mixture of hydrogen and oxygen in Example 2.32.