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 14.94QE

(a)

Interpretation Introduction

Interpretation:

Whether the system reaches equilibrium or not has to be determined.

Concept Introduction:

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

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 relation of equilibrium constant Kp and Kc is as follows:

  Kp=Kc(RT)Δn        (1)

Here, Δn is change in number of moles of gas.

The formula to calculate the value of Δn is as follows:

  Δn=(total number of moles ofgas on the product side)(total number of moles ofgas on the reactant side)        (2)

The value of Δn can be zero, negative and positive.

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 it 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 equilibrium constant for the above reaction is as follows:

  Q=[C]c[D]d[A]a[B]b

Here,

Q is the reaction quotient.

[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

Answer to Problem 14.94QE

The system is not in equilibrium.

Explanation of Solution

The given reaction is as follows:

  SO2(g)+Cl2(g)SO2Cl2(g)

Substitute 1 for the total number of moles of gas on product side and 2 for the total number of moles of gas on reactant side in equation (2).

  Δn=12=1

Rearrange equation (1) to calculate Kc.

  Kc=Kp(RT)Δn        (3)

The formula to convert degree Celsius to Kelvin is as follows:

  T(K)=T(°C)+273.15 K        (4)

Substitute 227 °C for T(°C) in equation (4) to calculate T.

  T(K)=227 °C+273.15 K=500.15 K

Substitute 1 for Δn, 5.1×102 for Kp, 500.15 K for T and 0.08206 Latm/molK for R in equation (3).

  Kc=5.1×102((0.08206 Latm/molK)(500.15 K))1=2.093

The concentration of SO2 can be calculated as follows:

  [SO2]=(1 g1 L)(1 mol64.066 g)=0.0156 M

The concentration of Cl2 can be calculated as follows:

  [Cl2]=(1 g1 L)(1 mol70.9 g)=0.0141 M

The concentration of SO2Cl2 can be calculated as follows:

  [SO2Cl2]=(45.5 g1 mL)(106 g1 g)(1 mL103 L)(1 mol134.96 g)=3.37×104 M

The formula to calculate Q for the given reaction is as follows:

  Q=[SO2Cl2][SO2][Cl2]        (5)

Substitute 3.37×104 M for [SO2Cl2], 0.0156 M for [SO2] and 0.0141 M for [Cl2] in equation (5).

  Q=3.37×104(0.0156)(0.0141)=1.53

Since Q is not equal to Kc, the system is not in equilibrium.

(b)

Interpretation Introduction

Interpretation:

The expected mass of SO2Cl2 at equilibrium has to be determined.

Concept Introduction:

The expression of the equilibrium constant for the above reaction is as follows:

  Kc=[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.

(b)

Expert Solution
Check Mark

Answer to Problem 14.94QE

The expected mass of SO2Cl2 is 0.058 g.

Explanation of Solution

The given reaction is as follows:

  SO2(g)+Cl2(g)SO2Cl2(g)

The ICE table for the above reaction is as follows:

EquationSO2+Cl2SO2Cl2Initial(M)0.01560.01410Change(M)xx+xEquilibrium(M)0.0156x0.0141xx

The expression to calculate Kc for the given reaction is as follows:

  Kc=[SO2Cl2][SO2][Cl2]        (6)

Substitute x for [SO2Cl2], 0.0156x for [SO2], 0.0141x for [Cl2] and 2.093 for Kc in equation (6).

  2.093=(x)(0.0156x)(0.0141x)x=(2.093)(0.0156x)(0.0141x)

Rearrange the above equation as follows:

  x20.507x+0.000219=0

Solve the quadratic equation for x.

  x=0.00043 M

Or,

  x=0.507 M

But x=0.507 M is rejected as it will result in negative concentrations of both SO2 and Cl2.

Therefore the concentration of SO2Cl2 is 0.00043 M. This means 0.00043 moles of SO2Cl2 are present in one litre of solution.

The mass of SO2Cl2 can be calculated as follows:

  Mass of SO2Cl2=(0.00043 mol)(134.96 g1 mol)=0.058 g

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Chapter 14 Solutions

Chemistry Principles And Practice

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