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Chapter 13: Q73E (page 759)

A student solved the following problem and found the equilibrium concentrations to be \(\left[ {S{O_2}} \right] = 0.590M\), \(\left[ {{O_2}} \right] = 0.0450M\), and \(\left[ {S{O_3}} \right] = 0.260M\). How could this student check the work without reworking the problem? The problem was: For the following reaction at \(60{0^0}C\):

\(2S{O_2}(g) + {O_2}(g) \rightleftharpoons 2S{O_3}(g)\)

\({K_c} = 4.32\)

What are the equilibrium concentrations of all species in a mixture that was prepared with \(\left[ {S{O_3}} \right] = 0.500M\), \(\left[ {S{O_2}} \right] = 0M\)and \(\left[ {{O_2}} \right] = 0.350M\)?

Short Answer

Expert verified

The equilibrium constant of all species in the mixture are

\(\begin{array}{c}\left[ {S{O_2}} \right] = 0.208M\\\left[ {{O_2}} \right] = 0.454M\\\left[ {S{O_3}} \right] = 0.292M\end{array}\)

Since these results doesn’t match the students results, we can conclude that the student’s work was wrong

Step by step solution

01

Finding reaction quotient:

We must find the reaction quotient \(\left( {{Q_c}} \right)\). If \(\left( {{Q_c}} \right) = \left( {{K_c}} \right)\)the system is already at equilibrium and the results are correct.

\(\begin{array}{c}{Q_C} = \frac{{{{\left[ {S{O_3}} \right]}^2}}}{{{{\left[ {S{O_2}} \right]}^2} \times \left[ {{O_2}} \right]}}\\ = \frac{{{{\left( {0.260} \right)}^2}}}{{{{\left( {0.590} \right)}^2} \times 0.0450}}\\ = 4.3155\\ \approx 4.32\end{array}\)

Since \(\left( {{Q_c}} \right) = \left( {{K_c}} \right)\) the student’s results are correct.

02

Find the equilibrium constant of all species:

Let us assume that the amount of \({\rm{S}}{{\rm{O}}_2}\)be x

\(\begin{array}{c}{K_C} = \frac{{{{\left[ {S{O_3}} \right]}^2}}}{{{{\left[ {S{O_2}} \right]}^2} \times \left[ {{O_2}} \right]}}\\4.32 = \frac{{{{\left( {0.500 - 2x} \right)}^2}}}{{{{\left( {2x} \right)}^2} \times \left( {0.350 + x} \right)}}\\4.32 = \frac{{0.25 - 2x + 4{x^2}}}{{1.4{x^2} + 4{x^3}}}\\4{x^2} - 2x + 0.25 = 17.28{x^3} + 6.048{x^2}\\17.28{x^3} + 2.048{x^2} + 2x - 0.25 = 0\\x = 0.104\end{array}\)

So, equilibrium constant of all species in the mixture are

\(\begin{array}{c}\left[ {S{O_2}} \right] = 2x = 0.208M\\\left[ {{O_2}} \right] = 0.350 + x = 0.454M\\\left[ {S{O_3}} \right] = 0.500 - 2x = 0.292M\end{array}\)

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Most popular questions from this chapter

The initial concentrations or pressures of reactants and products are given for each of the following systems. Calculate the reaction quotient and determine the direction) in which each system will proceed to leach equilibrium.

Question: A reaction is represented by this equation: \({K_c} = 1 \times 1{0^3}\)

(a) Write the mathematical expression for the equilibrium constant.

For which of the reactions in Exercise 13.16 does \({K_c}\) (calculated using concentrations) equal \({K_p}\)(calculated using pressures)?

(a) \({N_2}(g) + 3{H_2}(g)\rightleftharpoons 2N{H_3}(g)\)

(b) \(4N{H_3}(g) + 5{O_2}(g)\rightleftharpoons 4NO(g) + 6{H_2}O(g)\)

(c) \({N_2}{O_4}(g)\rightleftharpoons 2N{O_2}(g)\)

(d) \(C{O_2}(g) + {H_2}(g)\rightleftharpoons CO(g) + {H_2}O(g)\)

(e) \(N{H_4}Cl(s)\rightleftharpoons N{H_3}(g) + HCl(g)\)

(f) \(2\;Pb{\left( {N{O_3}} \right)_2}(s)\rightleftharpoons 2PbO(s) + 4N{O_2}(g) + {O_2}(g)\)

(g) \(2{H_2}(g) + {O_2}(g)\rightleftharpoons 2{H_2}O(l)\)

(h) \({S_8}(g)\rightleftharpoons 8\;S(g)\)

Cobalt metal can be prepared by reducing cobalt (II) oxide with carbon monoxide.

\(CoO(s) + CO(g) \rightleftharpoons Co(s) + C{O_2}(g)\)

\({K_c} = 4.90 \times 1{0^2}at55{0^o}C\)

What concentration of \(CO\) remains in an equilibrium mixture with \(\left[ {C{O_2}} \right] = 0.100M\)

Show that the complete chemical equation, the total ionic equation, and the net ionic equation for the reaction represented by the equation \({\rm{KI}}(aq) + {{\rm{I}}_2}(aq) \rightleftharpoons {\rm{K}}{{\rm{I}}_3}(aq)\) give the same expression for the reaction quotient. \({\rm{K}}{{\rm{I}}_3}\)is composed of the ions \({{\rm{K}}^ + }\) and \({{\rm{I}}_3}^ - .\)
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