Chemistry Principles And Practice
Chemistry Principles And Practice
3rd Edition
ISBN: 9781305295803
Author: David Reger; Scott Ball; Daniel Goode
Publisher: Cengage Learning
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Chapter 14, Problem 14.34QE

(a)

Interpretation Introduction

Interpretation:

If 0.50 mol of CO, 0.40 mol of H2O, 0.80 mol of CO2, and 0.90 mol of H2 is place in 1.0 L container then the direction of the following reaction has to be determined.

  CO(g)+H2O(g)CO2(g)+H2(g)

Concept Introduction:

The condition of equilibrium is a state of balance of processes that runs in opposite directions. At equilibrium, the formation of a product from the reactant balances the formation of reactant from the product. Also, the change in concentration of reaction and product seems to be negligible at the equilibrium state.

A reaction quotient Q is an algebraic form of equilibrium constant (Keq) for all concentrations including reaction concentrations at equilibrium. The reaction quotient Q can also help in prediction of direction of reaction when compared with the equilibrium constant (Keq).

The general equilibrium reaction is as follows:

  aA+bBcC+dD

Here,

A and B are the reactants.

C and D are products.

a and b are the stoichiometric coefficients of reactants.

c and d are the stoichiometric coefficients of products.

The expression of the reaction quotient for the above reaction is as follows:

  Q=[C]c[D]d[A]a[B]b

Here,

Kc is the equilibrium constant.

[C] is the concentration of C.

[D] is the concentration of D.

[A] is the concentration of A.

[B] is the concentration of B.

The concentration of reactants and products changes in order to bring reaction quotient and equilibrium constant closer. Therefore, the direction of reaction can be predicted as follows:

(1) If Q is less than Keq then the reaction moves to increase the concentration of products, which means reaction moves towards right direction.

(2)If Q is greater than Keq then the reaction moves to decrease the concentration of products, that means reaction moves towards the left direction.

(3)If Q is equal to Keq then the reaction is in equilibrium.

(a)

Expert Solution
Check Mark

Explanation of Solution

The given reaction occurs is as follows:

  CO(g)+H2O(g)CO2(g)+H2(g)        (1)

The concentration of CO can be calculated as follows:

  [CO]=(0.50 mol1.0 L)=5.0×101 M

The concentration of H2O can be calculated as follows:

  [H2O]=(0.40 mol1.0 L)=4.0×101 M

The concentration of CO2 can be calculated as follows:

  [CO2]=(0.80 mol1.0 L)=8.0×101 M

The concentration of H2 can be calculated as follows:

  [H2]=(0.90 mol1.0 L)=9.0×101 M

The expression to calculate Q for the chemical equation (1) is as follows:

  Q=[CO2][H2][CO][H2O]        (2)

Substitute 5.0×101 M for [CO], 4.0×101 M for [H2O], 8.0×101 M for [CO2],and 9.0×101 M for [H2] in equation (2).

  Q=(8.0×101 M)(9.0×101 M)(5.0×101 M)(4.0×101 M)=3.6

The value of Kc for a given reaction is 5.0. Since the value of Q is less than the value of Kc, therefore, the given reaction proceeds in a forward or right direction.

(b)

Interpretation Introduction

Interpretation:

If 0.01 mol of CO, 0.02mol of H2O, 0.03 mol of CO2, and 0.04 mol of H2 is place in 1.0 L container then the direction of the following reaction has to be determined.

  CO(g)+H2O(g)CO2(g)+H2(g)

Concept Introduction:

Refer to part (a).

(b)

Expert Solution
Check Mark

Explanation of Solution

The given reaction occurs is as follows:

  CO(g)+H2O(g)CO2(g)+H2(g)        (1)

The concentration of CO can be calculated as follows:

  [CO]=(0.01 mol1.0 L)=1×102 M

The concentration of H2O can be calculated as follows:

  [H2O]=(0.02 mol1.0 L)=2×102 M

The concentration of CO2 can be calculated as follows:

  [CO2]=(0.03 mol1.0 L)=3×102 M

The concentration of H2 can be calculated as follows:

  [H2]=(0.04 mol1.0 L)=4×102 M

The expression to calculate Q for the chemical equation (1) is as follows:

  Q=[CO2][H2][CO][H2O]        (2)

Substitute 1×102 M for [CO], 2×102 M for [H2O], 3×102 M for [CO2], and 4×102 M for [H2] in equation (2).

  Q=(3×102 M)(4×102 M)(1×102 M)(2×102 M)=6

The value of Kc for a given reaction is 5.0. Since the value of Q is greater than the value of Kc, therefore, the given reaction proceeds in a backward or left direction.

(c)

Interpretation Introduction

Interpretation:

If 1.22 mol of CO, 1.22 mol of H2O, 2.78 mol of CO2, and 2.78 mol of H2 is place in 1.0 L container then the direction of the following reaction has to be determined.

  CO(g)+H2O(g)CO2(g)+H2(g)

Concept Introduction:

Refer to part (a).

(c)

Expert Solution
Check Mark

Explanation of Solution

The given reaction occurs is as follows:

  CO(g)+H2O(g)CO2(g)+H2(g)        (1)

The concentration of CO can be calculated as follows:

  [CO]=(1.22 mol1.0 L)=1.22 M

The concentration of H2O can be calculated as follows:

  [H2O]=(1.22 mol1.0 L)=1.22 M

The concentration of CO2 can be calculated as follows:

  [CO2]=(2.78 mol1.0 L)=2.78 M

The concentration of H2 can be calculated as follows:

  [H2]=(2.78 mol1.0 L)=2.78 M

The expression to calculate Q for the chemical equation (1) is as follows:

  Q=[CO2][H2][CO][H2O]        (2)

Substitute 1.22 M for [CO], 1.22 M for [H2O], 2.78 M for [CO2], and 2.78 M for [H2] in equation (2).

  Q=(2.78 M)(2.78 M)(1.22 M)(1.22 M)=5.19

The value of Kc for a given reaction is 5.0. Since the value of Q is greater than the value of Kc, therefore, the given reaction proceeds in a backward or left direction.

(d)

Interpretation Introduction

Interpretation:

If 0.61 mol of CO, 1.22 mol of H2O, 1.39 mol of CO2, and 2.39 mol of H2 is place in 1.0 L container then the direction of the following reaction has to be determined.

  CO(g)+H2O(g)CO2(g)+H2(g)

Concept Introduction:

Refer to part (a).

(d)

Expert Solution
Check Mark

Explanation of Solution

The given reaction occurs is as follows:

  CO(g)+H2O(g)CO2(g)+H2(g)        (1)

The concentration of CO can be calculated as follows:

  [CO]=(0.61 mol1.0 L)=0.61 M

The concentration of H2O can be calculated as follows:

  [H2O]=(1.22 mol1.0 L)=1.22 M

The concentration of CO2 can be calculated as follows:

  [CO2]=(1.39 mol1.0 L)=1.39 M

The concentration of H2 can be calculated as follows:

  [H2]=(2.39 mol1.0 L)=2.39 M

The expression to calculate Q for the chemical equation (1) is as follows:

  Q=[CO2][H2][CO][H2O]        (2)

Substitute 0.61 M for [CO], 1.22 M for [H2O], 1.39 M for [CO2], and 2.39 M for [H2] in equation (2).

  Q=(1.39 M)(2.39 M)(0.61 M)(1.22 M)=8.9

The value of Kc for a given reaction is 5.0. Since the value of Q is greater than the value of Kc, therefore, the given reaction proceeds in a backward or left direction.

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Chapter 14 Solutions

Chemistry Principles And Practice

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