For the Haber process, N2(g) + 3 H2(g) ⇌ 2 NH3(g), Kp = 1.41 × 10^-9, at 500 °C. In an equilibrium mixture of the three gases at 500 °C, the partial pressure of H2 is 94.03 bar and that of N2 is 43.77 bar. What is the partial pressure of NH3 in this equilibrium mixture?

Question

For the Haber process, [latex]N_{2} (g) + 3 H_{2} (g) ⇌ 2 NH_{3} (g), K_{p} = 1.41 × 10^{-9}[/latex], at 500 °C. In an equilibrium mixture of the three gases at 500 °C, the partial pressure of [latex]H_{2}[/latex] is 94.03 bar and that of [latex]N_{2}[/latex] is 43.77 bar. What is the partial pressure of [latex]NH_{3}[/latex] in this equilibrium mixture?

Accepted Answer

Analyze We are given an equilibrium constant, [latex]K_{p}[/latex], and the equilibrium partial pressures of two of the three substances in the equation ([latex]N_{2} and H_{2}[/latex]), and we are asked to calculate the equilibrium partial pressure for the third substance ([latex]NH_{3}[/latex]).
Plan We can set [latex]K_{p}[/latex] equal to the equilibrium expression and substitute in the partial pressures that we know. Then we can solve for the only unknown in the equation.
Solve
We tabulate the equilibrium pressures:

[latex]\begin{array}{lcccc}&N_{2} (g)&+ 3 H_{2} (g) &⇌ &2 NH_{3} (g)\ ext{Equilibrium pressure bar}& ext{43.77 bar}& ext{94.03 bar}&&x\end{array}[/latex]

Because we do not know the equilibrium pressure of [latex]NH_{3}[/latex],we represent it with x. At equilibrium, the pressures must satisfy the equilibrium expression:

[latex]K_{p} =\frac{(P_{NH_{3}})²}{P_{N_{2}}(P_{H_{2}})³ }=\frac{x²}{(43.77)(94.03)³}= 1.41 × 10^{-9}[/latex]

We now rearrange the equation to solve for x:

x² = [latex](1.41 × 10^{-9})(43.77)(94.03)³ = 5.14 × 10^{-2}[/latex]

x = [latex]\sqrt{ 5.14 × 10^{-2}} = 0.227 bar = P_{NH_{3}}[/latex]

Check We can always check our answer by using it to recalculate the value of the equilibrium constant:

[latex]K_{p} =\frac{(0.227)²}{(43.77)(94.03)³} = 1.41 × 10^{-9}[/latex]

Question 15.10: For the Haber process, N2(g) + 3 H2(g) ⇌ 2 NH3(g), Kp = 1.41...

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