first order reactions - mississippi state · second order reactions (class i) 4 • rate...
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First Order Reactions
1
• Rate Law: Concentration with exponent of one
• Basic Reaction: R P– Rate doesn’t depend on the product; spontaneous
• Example: Radioactive decay
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First Order Reactions
2
• Example:
• Rate Law for A and B:– “The rate of decay of A is proportional to the amount of A.”
and
• Starting conditions (at t = 0):and
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Plotting First Order Reactions
3
• Plotting vs.
• Fit Parameters:– Intercept: – Slope:
ln(A
0/M)
t (s)
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Second Order Reactions (Class I)
4
• Rate Law: Concentration with exponent of two
• Basic Reaction: R+R P– Rate doesn’t depend on the product; spontaneous– Two reactant molecules collide and form product
• Example: 2(Cysteine) Cystine
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Second Order Reactions (Class I)
5
• Example:
• Rate Law for A and B:– “The rate of decay of A is proportional to amount of A2.”
and
• Starting conditions (at t = 0):and
![Page 6: First Order Reactions - Mississippi State · Second Order Reactions (Class I) 4 • Rate Law:Concentration with exponent of two × º × ç 6 • Basic Reaction:R+R P – Rate doesn’t](https://reader033.vdocuments.net/reader033/viewer/2022060606/605c5d4cc317f91772381093/html5/thumbnails/6.jpg)
Plotting Second Order Reactions
6
• Plotting vs.
• Fit Parameters:– Intercept: – Slope:
A‐1(M
‐1)
t (s)
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First vs. Second Order: Single Species
7
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Second Order Reactions (Class II)
8
• Rate Law: Concentration with overall order of two
• Basic Reaction: R1+R2 P– Rate doesn’t depend on the product; spontaneous– Two different reactant molecules collide and form product
• Example: DNA1 + DNA2 Duplex DNA
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Second Order Reactions (Class II)
9
• Example:
• Rate Law for A and B:– The rate laws for A and B are the same (Why?)– A and B must collide in order to react
and
• Starting conditions (at t = 0):and and
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Plotting Second Order Reactions
10
• Plotting vs. ln ln
• Fit Parameters:
– Intercept:
– Slope:ln(A/B)
t (s)
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Class I vs. Class II: A Special Case
11
• Example:
→
• What if A0 = B0?
ln ln
– This won’t work! ( 0)
• If initial concentrations are the same, Class II Class I, even though actual species are different!– A and B are used up identically and [A] is not distinguishable
from [B]
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General Case
12
• Rate Law: Concentration with exponent of two
• Solution: (Integration after separation of variables)– Same species, or A0=B0=C0=…
11
1 1
• Half Life:
/2 11
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Summary of Rate Laws
13Tinoco, p. 339.
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Determining Orders and Rate Constants
14
• Critical:Make sure you know the stoichiometry!
• Method 1: Plot concentration vs. time– Linear indicates zero‐order– Can use non‐linear fitting techniques
• Method 2: Plot vs. time– Does it look linear, parabolic, etc.?– Drawback: many points are needed to get slope
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Determining Orders and Rate Constants
15
• Method 3: Initial velocities– Initial velocity should reflect initial concentrations– Assumption: concentrations don’t change much– Example: If , doubling [B0] should quadruple initial rate
– If [A0], [B0], v, and orders are known, solve for k algebraically
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Determining Orders and Rate Constants
16
• Method 4: Elimination by excess– Add B in large molar excess compared to A– [B] won’t change much, so
– B will “drop out” of the rate law, measure [A] vs. t.