Energy/Reaction Coordinate Diagrams Thermodynamics, Kinetics
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Transcript of Energy/Reaction Coordinate Diagrams Thermodynamics, Kinetics
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Energy/Reaction CoordinateDiagrams
Thermodynamics, Kinetics Dr. Ron Rusay
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A Reaction Coordinate (Energy) Diagram
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Thermodynamic Quantities
Gibbs standard free energy change (DGo)
Enthalphy (DHo): the heat given off or absorbed during a reaction
Entropy (DSo): a measure of freedom of motion
DGo = DHo - TDSo
DG,DH,DS, DE are state functions
If DSo is small, compared to DHo, then DGo ≈ DHo
DE = q + wDH = qp
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• Most reactions are EXOTHERMIC and DGo ≈ DHo = (-)• But, there are many ENDOTHERMIC reactions such as
photosynthesis that occur.• In this case, entropy is significant and must be
considered in order for the reaction to be spontaneous and DGo = (-)
• ENTROPY (ΔS) is molecular disorder and related to an increase in molecular degrees of freedom, in this case rotational and vibrational energy states.
Entropy (ΔS)
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Example: PhotosynthesisEnergy Capture (Endergonic Reaction)
n CO2(g) + n H2O(g) + energy
DGo = DHo - TDSo
DHo = ?
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Photosynthesis Energy Capture (Endergonic Reaction)
n CO2(g) + n H2O(g) + energy
Energy
n CO2(g) + n H2O(g)
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Photosynthesis Energy Capture (Endergonic Reaction)
n CO2(g) + n H2O(g) + energy (CH2O) n (aq) + n O2(g)
(CH2O)n(aq) + n O2(g)
Energy
n CO2(g) + n H2O(g)
DE Reaction = E Products – E Reactants
DE Reaction = (+)An Endothermic (Endergonic) Reaction
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Photosynthesis Energy Capture (Endergonic Reaction)
n CO2(g) + n H2O(g) + energy (CH2O) n (aq) + n O2(g)
DGo = DHo – TDSo
DGo = ? DSo = ?
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Burning Gasoline (Octane)Exothermic Reactions : Energy Release
Reactants2 C8H18 + 25 O2Energy
2 C8H18 + 25 O2 16 CO2 + 18 H2O
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Burning Gasoline (Octane)Exothermic Reactions : Energy Release
Reactants2 C8H18 + 25 O2Energy
Products16 CO2 + 18 H2O
2 C8H18 + 25 O2 16 CO2 + 18 H2O
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Burning Gasoline (Octane)Exothermic Reactions : Energy Release
Reactants2 C8H18 + 25 O2Energy
Products16 CO2 + 18 H2O
DE Reaction = E Products – E Reactants
DE Reaction = (-)
An Exothermic (Exergonic) Reaction
2 C8H18 + 25 O2 16 CO2 + 18 H2O
DGo ≈ DHo = (-)
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Burning Gasoline (Octane)Exothermic Reactions : Energy Release
D H
16 CO2 + 18 H2O(Products are all the same.)
Are isomers the same thermodynamically?
2 C8H18 + 25 O2 16 CO2 + 18 H2O
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QuestionExothermic Reactions : Energy Release
D H
16 CO2 + 18 H2O(Products are all the same.)
What is the isomers’ order of decreasing thermodynamic stability?
A
B
C
D
1) A > B> C > D 2) D > C > B > A
2 C8H18 + 25 O2 16 CO2 + 18 H2O
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QuestionExothermic Reactions : Energy Release
D H
16 CO2 + 18 H2O(Products are all the same.)
Which isomer produces the most energy on burning?
A
B
C
D
1) A 2) B 3) C 4) D
2 C8H18 + 25 O2 16 CO2 + 18 H2O
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• DG,DH,DS, DE are state functions; independent of reaction pathway. They do not predict the rate of reaction, which depends on pathway.
• The reaction rate (the number of effective collisions in a period of time) relates to many factors.1. The concentrations of the reactants2. The phase of the reactants (s,l,g) 3. The activation energy (temperature)4. The pressure for gas phase reactions5. Geometry/steric effects of reactants and intermediates6. Catalysts
Thermodynamics & Kinetics
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The rate is mathematically represented by a rate constant k and the concentration of reactants:
The ORDER is represented by x and y in the rate law equation:
The overall order = x + y
Kinetics – Rate Laws
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• Notice the activation energy (Ea); it is the critical energetic barrier that must be overcome in order for a reaction to occur.
• There are different Ea barriers for different reactions, and Eamay vary for the same reaction depending on its mechanism.
Energy of Activation (Ea)
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• Temperature is a measure of a system’s AVERAGE kinetic energy.
• How does temperature affect the number of collisions and relate to the Energy of activation?
Factors that Affect Rates
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Which reaction would likely require a higher boiling organic solvent for the reaction to occur above room temperature in a reasonable amount of time?
Question
A B
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• B. Higher temperature = higher energy = more collisions
Answer
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• Geometry and steric effects impact the reaction rate.• A catalyst can have a profound influence, lowering the
Energy of activation and altering the mechanism.
Factors that Affect Rates
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• KINETICS relates to pathway, mechanism and Ea• THERMODYNAMICS relates to a state function:
DG,DH,DS, DE
Energy DiagramsKinetics vs. Thermodynamics
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• Which products are thermodynamically favored (i.e. more stable)?C + D (lower free energy)
• Which products are kinetically favored (i.e. form faster)?C+ D (lower Ea)
Energy DiagramsKinetics vs. Thermodynamics
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A reaction solvent with a relatively low b.p. favors products E + F.
• A = True; B = False
Question
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• For this energy diagram, which pathway is kinetically favored?
Red = A; Blue = B
Question
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• For this energy diagram, which pathway is thermodynamically favored?
Red = A; Blue = B
Question
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The reaction on the right does not occur at room temperature.
• A lower boiling solvent will favor the formation of C + D.
Question
A = True; B = False
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Energy Diagrams Transition States vs. Intermediates
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• A transition state occurs at an energy maxima. The one on the left shows a Br- bond breaking and a Cl- bond forming.
• Transition states cannot be isolated or directly observed.
• What might explain why transition states are so unstable?
Energy Diagrams Transition States
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• An intermediate occurs at an energy minimum. Intermediates often exist long enough to be observed. Bonds are NOT in the process of breaking or forming.
Energy Diagrams Intermediates
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For each of the diagrams below, will the transition state structure be more similar to the reactants or the products?
Energy Diagrams The Hammond Postulate
T.S. in exothermic reactions resemble reactants; endothermic resemble products
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Does the T.S. below resemble the bromide or chloride?
A) Bromide; B) Chloride
QuestionThe Hammond Postulate
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• Draw all possible resonance structures for the following molecule.
• Consider all formal charges and partial δ+ and δ- charges. Label each of those atoms nucleophilic (nu) or electrophilic (el) in each resonance structure.
Nucleophiles and Electrophiles React General Organic Reactions
O
O
O
NH2
HO
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• Using OH- as a nucleophile and H+ as an electrophile, draw all possible products for their respective reactions with your resonance structures showing arrows to show electron movements.
Nucleophiles and Electrophiles General Organic Reactions
O
O
O
NH2
HO