Chemical Thermodynamics: Entropy, Free Energy and Equilibrium Chapter 18 18.1-18.6 Chemical Thermodynamics  Science of interconversion of energy      Heat into other forms of energy Amount of heat gained/released.

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Transcript Chemical Thermodynamics: Entropy, Free Energy and Equilibrium Chapter 18 18.1-18.6 Chemical Thermodynamics  Science of interconversion of energy      Heat into other forms of energy Amount of heat gained/released. 

Chemical Thermodynamics:
Entropy, Free Energy and
Equilibrium
Chapter 18
18.1-18.6
Chemical Thermodynamics
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Science of interconversion of energy
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Heat into other forms of energy
Amount of heat gained/released from a system
Spontaneity of a reaction
Gibbs free energy function
Relationship between Gibbs Free Energy and
chemical equilibrium
Spontaneous Processes
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Main objective
Spontaneous Reaction- a reaction does occur
under specific conditions
Non-spontaneous Reaction- a reaction does
not occur under specific conditions
Spontaneous Processes
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A waterfall runs downhill
A lump of sugar dissolves in a cup of coffee
At 1 atm, water freezes below 0ºC and ice
melts above 0ºC
Heat flows from a hotter object to a colder
object
Iron exposed to oxygen and water forms rust
Spontaneous Processes
Spontaneous Processes
Does a decrease in enthalpy mean a reaction
proceeds spontaneously?
Spontaneous reactions
CH4 (g) + 2O2 (g)
H+ (aq) + OH- (aq)
H2O (s)
NH4NO3 (s)
CO2 (g) + 2H2O (l) DH0 = -890.4 kJ
H2O (l) DH0 = -56.2 kJ
H2O (l) DH0 = 6.01 kJ
H2O
NH4+(aq) + NO3- (aq) DH0 = 25 kJ
Entropy
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To predict spontaneity we need:
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Change in enthalpy
Entropy
Entropy- a measure of the randomness or disorder
of a system.
↑ Disorder = ↑ Entropy
Entropy
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New Deck Order
Shuffled Deck Order
Probability
Ordered state
Disordered State
Microstates and Entropy
Microstates and Entropy
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Boltzmann, 1868
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S = k ln W
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k = 1.38 x 10-23 J/K
↑ W = ↑ Entropy
∆ S = Sf – S i
∆ S = k ln Wf
Wi
Wf > Wi then DS > 0
Wf < Wi then DS < 0
Entropy and Disorder
If the change from initial to final results in an increase in randomness
Sf > Si
DS > 0
For any substance, the solid state is more ordered than the
liquid state and the liquid state is more ordered than gas state
Ssolid < Sliquid << Sgas
Entropy and Disorder
Entropy and Disorder
How does the entropy of a system change for
each of the following processes?
(a) Forming sucrose crystals from a supersaturated solution
Randomness decreases Entropy decreases (DS < 0)
(b) Heating hydrogen gas from 600C to 800C
Randomness increases
Entropy increases (DS > 0)
Entropy and Disorder
Standard Entropy
The standard entropy of reaction (DS0rxn ) is the entropy
change for a reaction carried out at 1 atm and 250C.
The Second Law of
Thermodynamics
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The entropy of the universe increases in a
spontaneous process and remains unchanged
in an equilibrium process.
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Importance?
Spontaneous process: DSuniv = DSsys + DSsurr > 0
Equilibrium process: DSuniv = DSsys + DSsurr = 0
Entropy Changes in the System
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To calculate ΔSuniv, we need both ΔSsys ΔSsurr
ΔSsys
aA + bB
cC + dD
DS0rxn = S nS0(products) - S mS0(reactants)
Entropy Changes in the System
Entropy Changes in the System
When gases are produced (or consumed)
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If a reaction produces more gas molecules than it
consumes, DS0 > 0.
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If the total number of gas molecules diminishes,
DS0 < 0.
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If there is no net change in the total number of gas
molecules, then DS0 may be positive or negative
BUT DS0 will be a small number.
Entropy Changes in the System
Entropy Changes in the
Surroundings
Entropy Changes in the
Surroundings
ΔSsurr = -ΔHsys
T
Using the information from Example 18.2, determine whether or
not the reaction is spontaneous.
N2(g) + 3H2(g) → 2 NH3(g)
ΔHºrxn = -92.6 kJ/mol
ΔSsys = -199 J/K ∙ mol
ΔSsurr = -(-92.6 x 1000) J/mol
298 K
ΔSsurr = 311 J/mol
ΔSuniv = ΔSsys + ΔSsurr
ΔSuniv = -199 J/K ∙ mol + 311 J/mol
ΔSUNIV = 112 J/K ∙ mol
The Third Law of Thermodynamics
and Absolute Entropy
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Third Law of
Thermodynamics- the
entropy of a perfect
crystalline substance is
zero at the absolute zero
of temperature.
Gibbs Free Energy
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Predicts the direction of a spontaneous
reaction.
Uses properties of the system to calculate.
For a constant pressure-temperature process:
DG = DHsys -TDSsys
DG < 0
The reaction is spontaneous in the forward direction.
DG > 0
The reaction is nonspontaneous as written. The
reaction is spontaneous in the reverse direction.
The reaction is at equilibrium.
DG = 0
Standard Free-Energy Changes
The standard free-energy of reaction (DG0rxn) is the freeenergy change for a reaction when it occurs under standardstate conditions.
Standard free energy of
formation (DG0f ) is the free-energy
change that occurs when 1 mole
of the compound is formed from its
elements in their standard states.
0
DGrxn
= S nDG0f (products) - S mDG0f (reactants)
Standard Free-Energy Changes
Factors Affecting ΔG
Free Energy and Chemical
Equilibrium
DG = DG0 + RT lnQ
R is the gas constant (8.314 J/K•mol)
T is the absolute temperature (K)
Q is the reaction quotient
At Equilibrium
DG = 0
Q=K
0 = DG0 + RT lnK
DG0 = - RT lnK
Free Energy and Chemical
Equilibrium
Free Energy and Chemical
Equilibrium
Free Energy and Chemical
Equilibrium
Thermodynamics of a Rubber Band