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Section 14.5 Activation Energy and Temperature Bill Vining SUNY Oneonta.

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Presentation on theme: "Section 14.5 Activation Energy and Temperature Bill Vining SUNY Oneonta."— Presentation transcript:

1 Section 14.5 Activation Energy and Temperature Bill Vining SUNY Oneonta

2 Activation Energy and Temperature In this section… a.Reaction coordinate diagrams b.The Arrhenius equation c.Temperature, E a and k d.Graphical determination of Ea

3 Reaction Coordinate Diagrams

4 Numerical connection between E a and ΔE

5 Activation Energy, Temperature and Rate

6 Trends: As E a decreases, rate increases As T increases, rate increases

7 Why do reactions go faster at higher temperature?

8 Why do reactions go faster with lower activation energy?

9 The Arrhenius Equation k = rate constant A = frequency factor E a = activation energy R = gas constant (8.3145 J/K ∙mol) T = temperature (K) Trends: As T↑: As E a ↑:

10 The Arrhenius Equation: Two Point Version k 1 = rate constant at temperature 1 k 2 = rate constant at temperature 2 T 1 = temperature 1 (K) T 2 = temperature 2 (K) E a = activation energy R = gas constant (8.3145 J/K ∙mol) General Use: There are five variables. If you know 4 of Them you can solve for the 5 th.

11 The Arrhenius Equation: Two Point Version The activation energy for the gas phase decomposition of t-butyl propionate is 164 kJ. C 2 H 5 COOC(CH 3 ) 3 (g)  (CH 3 ) 2 C=CH 2 (g) + C 2 H 5 COOH(g) The rate constant for this reaction is 3.80 × 10 -4 s -1 at 528 K. What is the rate constant at 569 K?

12 The Arrhenius Equation: Two Point Version The rate of a reaction triples when the temperature is increased from 280 o C to 300 o C. What is the activation energy?

13 The Arrhenius Equation: Graphical Determination of E a k = rate constant A = frequency factor E a = activation energy R = gas constant (8.3145 J/K ∙mol) T = temperature (K) y = b + m x Collect k vs. temperature data Plot ln(k) vs. 1/T E a = - slope x R

14 Graphical Determination of E a

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