Chapter 18 Lecture - Chemical Thermodynamics PDF

Summary

This is a lecture on Chapter 18, Chemical Thermodynamics, covering entropy, Gibbs free energy, and examples. The document contains sections and outlines for each topic, with examples to illustrate the concepts. Includes numerical problems.

Full Transcript

Chapter 18
Chemical
Thermodynamics

CHY 102
Chapter Outline
Section 18.1 Entropy and Spontaneity

Section 18.2 Entropy Changes

Section 18.3 Entropy and Temperature

Section 18.4 Gibbs Free Energy

Section 18.5 Free-Energy Changes and Temperature

Section 18.6 Gibbs Free Energy and Equilibrium
 18.1: Entropy and Spontaneity
Entropy (S) is a measure of the degree of disorder or randomness in a system

Entropy of a system increases whenever there is:
A phase change from a more condensed to less condensed phase (solid à liquid, liquid à gas)
Ø Solids are highly organized, liquids less so, gas particles move randomly

An increase in temperature within a given phase
Ø More kinetic energy increases the motion of the particles

An increase in the number of gas particles or dissolution of a solid in an aqueous solution
Ø Increase in number of particles provides more ways for the system’s energy to be distributed
 18.1: Entropy and Spontaneity
Example - Determine the sign of ΔS for the following processes:

a. 2 KClO3(s) → 2 KCl(s) + 3 O2(g) ΔS = + The number of particles increases, and a gas is formed

b. CO2(g) → CO2(s) ΔS = − A gas becomes a solid

c.

ΔS = + A solid becomes a gas

d. condensation appearing on bathroom mirror after a shower ΔS = − A gas becomes a liquid
 18.1: Entropy and Spontaneity
Entropy increases when there are more energetically equivalent ways to arrange the components of
that system.

Entropy was defined mathematically by Boltzman in the 1870s
k = Boltzman constant = 1.38 x 1023 J/K
S = k ln W W = the number of energetically equivalent arrangements
(microstates) possible for the system

What are microstates?
Consider a box with a divider down the middle containing two particles on the left side

A on top B on top A and B both A and B both
B on bottom A on bottom on top on bottom

Since there are four possible arrangements for this system, W=4
 18.1: Entropy and Spontaneity
If, in the last example, the divider were to be removed:

16 microstates
1 macrostate

There are now 16 possible arrangements, therefore W=16.

For any system, we can calculate W as:
X = # of locations
n
W=X n = # of particles

In the above example, there are two particles and four possible locations in which the particles can be,
so W = 42 = 16

Equivalent microstates form a macrostate, and the most probable macrostate is the one containing
the highest number of microstates.
Each circle represents a microstate. Which macrostate is most
probable?

B A
A. A and B together
A B
A B
B. A and B in separate
locations
A B B A A
C. A in top left, B in bottom
area B

D. All of the above are equally
probable. A B B

B A A
Each circle represents a microstate. Which macrostate is most
probable?

B A
A. A and B together 3
A B
A B
B. A and B in separate 6
locations
A B B A A
C. A in top left, B in bottom 1
area B

D. All of the above are equally
probable. A B B

B A A
 18.1: Entropy and Spontaneity
In general, the tendency towards disorder is a statistical
probability; a system will spontaneously move to a more
spread-out arrangement
Ø A more disordered system is more probable than an ordered
one

The criteria for spontaneity are not solely based on the
entropy change for the system. The entropy change of the
surroundings must also be considered, and how the system
and surroundings together affect the total entropy of the
universe Sfewer moles < Smore moles

Ø Processes that decrease the entropy of a system can still be
spontaneous

The Second Law of Thermodynamics states that 2NH3 à N2 + H2
spontaneous processes always result in an overall increase
in entropy, S, of the universe
 18.2 Entropy Changes
The third law of thermodynamics states that the entropy of a pure, perfectly ordered, crystalline
substance at absolute zero is zero:

Scrystal (0 K) = 0

At T = 0K, there is no thermal energy and the particles in a perfectly ordered crystal would exist in a
single microstate:

Scrystal = k ln W = k ln 1 = 0

Standard molar entropies, S°, are calculated based on the third law of thermodynamics, and these
can be used to calculate standard changes in entropy, ΔS°:
DS rxn

= å m[S  (products)] - å n[S (reactants)]
Where m and n are the coefficients of the products and reactants from the balanced chemical
equation, and standard thermodynamic conditions are 298 K, 1 atm gas pressure, and 1 M solute
concentration.
Standard Entropies at 298 K of Selected Substances

Compound J Compound J
S
S

(state) mol × K (state) mol × K
CO2(g) 213.8 HCl(g) 186.9
CaO(s) 38.1 Hg(l) 75.9
CaCO3(s) 91.7 Hg(g) 175.0
H2(g) 130.7 I2(s) 116.1
H2O(l) 70.0 I2(g) 260.7
H2O(g) 188.8 O2(g) 205.2
 18.2 Entropy Changes
Example - Predict the sign of ΔS and calculate the standard entropy change associated with the
reaction of gaseous hydrogen and gaseous oxygen to form water vapor.

Step 1: Write out the balanced chemical equation

2 H2(g) + O2(g) → 2 H2O(g)

Prediction: The number of moles of gases decreases in the reaction, so ΔS will be negative (−).

Step 2: Calculate the standard change in entropy using standard entropy data from the table
DS rxn

= å m[S  (products)] - å n[S (reactants)]

DS rxn

= 2S  ( H 2 O(g)) - [2S  ( H2(g)) + S  (O2(g))]

æ J ö é æ J ö æ J öù
DS 
= 2 mol ç 188.8 ÷ - ê2 mol ç 130.7 mol × K ÷ + 1 mol ç 205.2 mol × K ÷ ú
rxn
è mol × K ø ë è ø è øû
J
DS rxn

= -89.0
K
 18.3: Entropy and Temperature
An overall change in entropy is equal to the change in entropy of the system plus the change in
entropy of the surroundings:

ΔS univ = ΔS sys + ΔS surr

For a process to be spontaneous, ∆Suniv must be positive

The entropy change for the system may be negative, but the
process still be spontaneous
 18.3: Entropy and Temperature
For an isothermal process (i.e., no heat transfer between system and surroundings), and at constant
pressure the entropy change of the surroundings is related to the thermal energy change of the
system by:

-DH sys
ΔS surr =
T

Example – Calculate ΔSsurr and ΔSuniv for the reaction of gaseous hydrogen and gaseous oxygen to
form 2 mol of water vapor at 298 K

Step 1: Write the balanced chemical equation

2 H2(g) + O2(g) → 2 H2O(g)
Step 2: Calculate DH rxn


Ø Look up DH f values in Appendix A.1 of textbook: H2O(g) = -241.8 kJ/mol, H2 and O2 are in their elemental
state = 0 kJ/mol

DH rxn

= å m[ DH f (products)] - å n[ DH f (reactants)]

DH rxn

= 2 ( DH f (H2O(g)) - [2 ( DH f (H2(g)) + DH f(O2 )(g))]

æ kJ ö é æ kJ ö æ kJ ö ù
DH 
rxn
= 2 mol ç -241.8 ÷ - ê2 mol ç 0 ÷ + 1 mol ç 0 mol ÷ ú
è mol ø ë è mol ø è øû

DH rxn

= -483.6 kJ
Step 3: calculate ΔSsurr
-DH sys
ΔS surr =
T
-( -483.6 kJ) 1000 J
DS surr

= ´
298 K 1 kJ

J
DS surr

= 1.62 ´ 103
K

Step 4: Calculate ΔSsys and ΔSuniv
Ø We calculated ΔSsys for this reaction in the previous example; ΔSsys = -89.0 J/K

ΔS univ = ΔS sys + ΔS surr

J J
ΔS univ = -89.0 + 1620
K K
J
ΔS univ = 1530
K
 18.4 Gibbs Free Energy
Gibbs free energy, G, is a state function that an be used for predicting if a process is spontaneous at
a given temperature:
G = H - TS

For a chemical reaction occurring under standard conditions but nonstandard temperature, the change
in Gibbs free-energy is:
DG  = DH  -T DS 
∆G° = - à Reaction is spontaneous in the forward direction
∆G° = + à Reaction is spontaneous in the reverse direction
∆G° = 0 à Reaction is at equilibrium

Example - Determine ΔG° for the reaction of hydrogen and oxygen to form water given ΔS° = -89J/K
and ΔH° = -483.6 kJ.
2 H2(g) + O2(g) → 2 H2O(g)

æ Jö æ 1 kJ ö
DG  = DH  -T DS  DG  = -483.6 kJ - 298 K ç -89.0 ÷ ç 1000 J ÷ DG  = -457.1 kJ
è Kø è ø
 18.4 Gibbs Free Energy
The standard free energy of formation, DG f , is the free-energy change associated with the
o

formation of a substance from its component elements, in their standard states.

DG rxn

= å m[ DG f (products)] - å n[ DG f (reactants)]

Example - Calculate DG rxn

for the combustion of propane. Compound ∆Gf°
(kJ/mol)
C3H8(g) + 5 O2(g) → 3 CO2(g) + 4 H2O(l) C3H8(g) -23.4
CO2(g) -394.4
Solution: Use standard free energy of formation values to calculate ∆Grxn° H2O(l) -237.1

DG rxn

=[3DG f (CO2(g)) + 4DG f(H2O(l))] - [ DG f(C3H8(g)) + 5DG f(O2(g))]

é æ kJ ö æ kJ ö ù é æ kJ ö æ kJ ö ù
DG 
rxn
= ê3 mol ç -394.4 ÷ + 4 mol ç -237.1 ÷ -
ú ê1 mol ç -23.4 ÷ + 5 mol ç 0 mol ÷ ú
ë è mol ø è mol ø û ë è mol ø è øû

DG rxn

=( -2131.6 kJ) - ( -23.4 kJ)= -2108.2 kJ
 
Determine DG rxn for the following reaction:

2 A(g) + B2(g) → 2 AB(g)

A. −400 kJ
B. −250 kJ
C. −200 kJ
D. −100 kJ
E. −50 kJ
Compound(state) 𝚫𝑮∘𝐟 (kJ/mol)

A(g) 0
B2(g) −100
AB(g) −150
 
Determine DG rxn for the following reaction:

2 A(g) + B2(g) → 2 AB(g)

DG rxn

= å m[ DG f (products)] - å n[ DG f (reactants)]
A. −400 kJ
B. −250 kJ 𝑘𝐽 𝑘𝐽 𝑘𝐽
Δ𝐺°!"# = 2 𝑚𝑜𝑙 −150 − 2 𝑚𝑜𝑙 0 + 1 𝑚𝑜𝑙 −100
𝑚𝑜𝑙 𝑚𝑜𝑙 𝑚𝑜𝑙
C. −200 kJ
D. −100 kJ 𝚫𝑮°𝒓𝒙𝒏 = −𝟐𝟎𝟎 𝒌𝑱
E. −50 kJ
Compound(state) 𝚫𝑮∘𝐟 (kJ/mol)

A(g) 0
B2(g) −100
AB(g) −150
 18.5 Free-Energy Changes and Temperature
Standard values are measured at 298K. ∆H and ∆S values only vary slightly with temperature, so
standard values can be used for them at temperatures other than 298K

One way ∆G can be calculated at temperatures that are not 298K is by calculating ∆H° and ∆S°, then
using ΔG = ΔH° – TΔS°

We can also determine the temperature at which a reaction becomes spontaneous, i.e., when ∆G=0:

ΔG = ΔH – TΔS = 0

DH
T=
DS

T will provide the minimum temperature at which the forward reaction is spontaneous.
 18.5 Free-Energy Changes and Temperature
Example - Determine the minimum temperature for the spontaneous vaporization of liquid mercury
using data from the table below
Hg(l) → Hg(g) Compound ∆S° (J/mol・K)
Solution Hg(g) 175.0
J J J Hg(l) 75.9
DS = 175.0

- 75.9 DS  = 99.1
mol × K mol × K mol × K Compound ∆H° (kJ/mol)
Hg(g) 61.4
𝑘𝐽 𝑘𝐽 𝑘𝐽
Δ𝐻°!"# = 1 𝑚𝑜𝑙 61.4 − 1 𝑚𝑜𝑙 0 = 61.4 Hg(l) 0 (elemental state)
𝑚𝑜𝑙 𝑚𝑜𝑙 𝑚𝑜𝑙

kJ
61.4
DH mol
T= = = 620 K
DS J æ 1 kJ ö
99.1 ç
K è 1000 J ÷ø

∴ The vaporization of mercury becomes spontaneous at temperatures above 620 K.
 18.6 Gibbs Free Energy and Equilibrium
For other nonstandard conditions, the change in free energy for a reaction can be calculated as:

ΔG = ΔG° + RT ln Q
Reaction Quotient
Gas constant Temperature (QC for aqueous
8.314 J mol-1 K-1 (K) QP for gas)

Recall that Q occurs under nonequilibrium conditions. The result of the above equation tells us the direction
in which the reaction will proceed:

Ø ΔG = negative à reaction proceeds spontaneously
Ø ΔG = positive à reaction does not proceed spontaneously

Ø ΔG = 0 à reaction is at equilibrium

At equilibrium, Q = K and ΔG = 0, so the above equation becomes:

ΔG° = -RT ln K
K < 1 à The equilibrium position lies closer to the lower-
energy reactants
When Q = 1, ΔG > 0 à The reverse process is spontaneous

K = Q & ΔG = 0 à No net change
in forward or reverse direction

K > 1 à The equilibrium position lies closer to the lower-
energy products
When Q = 1, ΔG < 0 à The forward process is spontaneous
 18.6 Gibbs Free Energy and Equilibrium
Example – a) Calculate ΔG for the Haber process at 365 K for a mixture of 1.5 atm N2, 4.5 atm H2, and
0.75 atm NH3, b) In which direction is the reaction currently proceeding?

N2(g) + 3 H2(g) ⇌ 2 NH3(g)

a) Step 1: Start by calculating ΔG° from DG fvalues found in Appendix A.1.

æ kJ ö
DG  = 2 mol ç -16.4 ÷ - [0 + 0]= -32.8 kJ
è mol ø
Step 2: Calculate Q
(PNH )2
Qp = 3

(PN )(PH )3
2 2

(0.75)2 -3
Qp = = 4.1 ´ 10
(1.5)(4.5)3
Step 3: Plug your calculated values for ΔG° and 𝑄 into the ∆G equation

ΔG = ΔG° + RT ln Q

kJ æ J 1 kJ ö
DG = -32.8 + ç 8.3145 ´ ÷ (365 K) ln(4.1 ´ 10-3 )
mol è mol × K 1000 J ø

DG = -49.5 kJ/mol

b) Since ∆G is negative, the system is not at equilibrium and the reaction is occurring spontaneously in
the forward direction
Given the ∆G° value calculated for the Haber process in the last example,
what is the equilibrium constant for the Haber process at 298 K.

A. 5.6 x 105

B. 1.01

C. 4.74 x 108

D. 1.02 x 103
Given the ∆G° value calculated for the Haber process in the last example,
what is the equilibrium constant for the Haber process at 298 K.

ΔG 
-
ΔG° = -RT ln K K=e RT
A. 5.6 x 105

B. 1.01
DG  -( -32.8 kJ) 1000 J
Calculate exponent: - = ´ = 13.24
RT æ J ö 1 kJ
C. 4.74 x 108 ç 8.3145 mol × K ÷ (298 K)
è ø
D. 1.02 x 103
Now solve for 𝐾:

K = e 13.24

K = 5.6 × 105