Presentation is loading. Please wait.

Presentation is loading. Please wait.

Previously in Chem 104: How to determine Rate Law How to determine rate constant, k Recognizing Plots Using Integrated Rate Laws to determine concentrations.

Published byAndra Casey Modified over 9 years ago

Similar presentations

Presentation on theme: "Previously in Chem 104: How to determine Rate Law How to determine rate constant, k Recognizing Plots Using Integrated Rate Laws to determine concentrations."— Presentation transcript:

1 Previously in Chem 104: How to determine Rate Law How to determine rate constant, k Recognizing Plots Using Integrated Rate Laws to determine concentrations vs time Using the Arrhenius Eqn to find k at new Temp TODAY Half lives the collision theory of kinetics Reaction Coordinates Importance of Rate Law: Mechanism What is A? E a ? QUIZ! Watch for it This weekend!

2 [rgt] o Time, sec [rgt] t½ = ½ [rgt] o [rgt] t¼ = ¼ [rgt] o t ½ t¼t¼

3 Radioactive Decay and Half Lives Technetium Radiopharmaceuticals, Tc

4 The Collision Theory of Reactions - Reactions result when atoms/molecules collide with sufficient energy to break bonds - Molecules must collide in an orientation that leads to productive bond cleavage and/or formation Collision Theory Connects Macroscopic and Microscopic Perspectives of Kinetics -The more molecules in a volume, the more collisions, or, the reaction occurrence depends on concentration

5 Collision Theory and: The Rate Law: the Macroscopic View [H 2 O 2 ] o Time, sec Rate = k[H 2 O 2 ][I-] Why concentrations affect rate

6 The Collision Theory: why higher temperatures help - Reactions result when atoms/molecules collide with sufficient energy to break bonds - Molecules at a higher temperature move faster— have a greater energy (energy distribution increases)

7 Energetics of a Reaction are Summarized in a Reaction Coordinate Ex. 1: For a single step reaction: A + A  B E a : the “sufficient energy” in collision  H f : net reaction enthalpy 2A rgts B prdt energy Reaction progress

8 Collision Theory and: The Rate Law: the Macroscopic View The Rate Law: the Microscopic View [H 2 O 2 ] o Time, sec Rate = k[H 2 O 2 ][I-] Why concentrations affect rate

9 The Importance of the Rate Law The Rate Law specifies the the molecularity of the Rate-Determining Step, it specifies which collisions most affect rate. The Rate Determining Step is the process (collision) that has E a, the energy of activation, the most energetic step of reaction.

10 Connecting Hoses to Water the Garden ½ inch, 4 gal/min 3/4 inch, 8 gal/min 1 inch, 16 gal/min How do you connect these 3 hoses to deliver water at the fastest rate? All will have same rate— Limited by the 4 gal/min, ½ inch hose

11 The rate determining step at the Burgmayer’s: Andrew…

12 In the reaction: 2 H 2 O 2  O 2 + 2 H 2 O the Rate Law is: Rate rxn = k’ [H 2 O 2 ] o [I - ] o And so the r.d.s. involves one H 2 O 2 and one I- Maybe like this?

13 the Rate Law is: Rate rxn = k’ [H 2 O 2 ] o [KI] o Step 1: H 2 O 2 + I -  H-O-I + OH - slow Step 2: H-O-I + H 2 O 2  O 2 + H 2 O + I - + H + fast Step 3: H + + OH -  H 2 O v. fast Net reaction: 2 H 2 O 2  O 2 + 2 H 2 O If this is the slow step, how do we get to products?

14 the Rate Law is: Rate rxn = k’ [H 2 O 2 ] o [KI] o Step 1: H 2 O 2 + I -  H-O-I + OH - k = 10 -3 sec -1 Step 2: H-O-I + H 2 O 2  O 2 + H 2 O + I - + H + k = ? sec -1 Step 3: H + + OH -  H 2 O k = 10 13 sec -1 Net reaction: 2 H 2 O 2  O 2 + 2 H 2 O k = 10 -3 sec -1 These steps are called Elementary Reaction Steps. Here, all are bi-molecular (involve 2 species)

15 The Arrhenius Equation k = Ae -Ea/RT Activation energy: We now understand what that is What is this?

16

17 H2O2H2O2 I-I-

18 Bad orientation: no productive reaction occurs

19 I-O-HOH - If collision orientation is favorable, a reaction occurs

20 There may be several good collision orientations

21 The Arrhenius Equation k = Ae -Ea/RT Activation energy: We now understand what that is Orientation Factor

22 Energetics of a Reaction Summarized in a Reaction Coordinate Ex. 2: For a multi step reaction: 2 H 2 O 2  O2 + 2 H 2 O HfHf 2 H 2 O 2 energy Reaction progress 2H 2 O + O 2

23 Energetics of a Reaction Summarized in a Reaction Coordinate Ex. 2: For a multi step reaction: 2 H 2 O 2  O 2 + 2 H 2 O EaEa HfHf energy Reaction progress H-O-I + OH - intermediates 2 H 2 O 2 2H 2 O + O 2 Step 1: + I - - I - Transition state Step 2 Step 3

24

Download ppt "Previously in Chem 104: How to determine Rate Law How to determine rate constant, k Recognizing Plots Using Integrated Rate Laws to determine concentrations."

Similar presentations

Ch. 16 – Reaction Energy and Reaction Kinetics

Ch. 16 – Reaction Energy and Reaction Kinetics
Chemical Kinetics Reaction rate - the change in concentration of reactant or product per unit time.

Chemical Kinetics Reaction rate - the change in concentration of reactant or product per unit time.
CHEMICAL KINETICS CHAPTER 17, Kinetics Fall 2009, CHEM 1310 1.

CHEMICAL KINETICS CHAPTER 17, Kinetics Fall 2009, CHEM
Kinetics Quick Review. Radioactive Decay and Kinetics.

Kinetics Quick Review. Radioactive Decay and Kinetics.
Reaction Rates (Chapter 13)

Reaction Rates (Chapter 13)
RATES OF REACTION SUROVIEC SPRING 2014 Chapter 13.

RATES OF REACTION SUROVIEC SPRING 2014 Chapter 13.
Chapter 14 Chemical Kinetics *concerned with speed or rates of chemical reactions reaction rate- the speed at which a chemical reaction occurs reaction.

Chapter 14 Chemical Kinetics *concerned with speed or rates of chemical reactions reaction rate- the speed at which a chemical reaction occurs reaction.
- Explaining Reaction Rates -

- Explaining Reaction Rates -
1 MECHANISMS A Microscopic View of Reactions Sections 15.5 and 15.6 How are reactants converted to products at the molecular level? Want to connect the.

1 MECHANISMS A Microscopic View of Reactions Sections 15.5 and 15.6 How are reactants converted to products at the molecular level? Want to connect the.
Prentice-Hall © 2007 General Chemistry: Chapter 14 Slide 1 of 61 14-8 Theoretical Models for Chemical Kinetics  Kinetic-Molecular theory can be used to.

Prentice-Hall © 2007 General Chemistry: Chapter 14 Slide 1 of Theoretical Models for Chemical Kinetics  Kinetic-Molecular theory can be used to.
CHE 112 - MODULE 3 CHAPTER 15 LECTURE NOTES. Chemical Kinetics  Chemical kinetics - study of the rates of chemical reactions and is dependent on the.

CHE MODULE 3 CHAPTER 15 LECTURE NOTES. Chemical Kinetics  Chemical kinetics - study of the rates of chemical reactions and is dependent on the.
Chapter 15 Kinetics. Kinetics Deals with the rate of chemical reactions Deals with the rate of chemical reactions Reaction mechanism – steps that a reaction.

Chapter 15 Kinetics. Kinetics Deals with the rate of chemical reactions Deals with the rate of chemical reactions Reaction mechanism – steps that a reaction.
Chemical Kinetics Rates of chemical reaction - definition of reaction rate - integrated and differential rate law - determination of rate law Mechanism.

Chemical Kinetics Rates of chemical reaction - definition of reaction rate - integrated and differential rate law - determination of rate law Mechanism.
Integration of the rate laws gives the integrated rate laws

Integration of the rate laws gives the integrated rate laws
Chemical Kinetics Collision Theory: How reactions takes place

Chemical Kinetics Collision Theory: How reactions takes place
16.2.1 Explain that reactions can occur by more than one step and that the slowest step determines the rate of the reaction (rate- determining step) 16.2.2.

Explain that reactions can occur by more than one step and that the slowest step determines the rate of the reaction (rate- determining step)
Chemical Kinetics Chapter 15 H 2 O 2 decomposition in an insect H 2 O 2 decomposition catalyzed by MnO 2.

Chemical Kinetics Chapter 15 H 2 O 2 decomposition in an insect H 2 O 2 decomposition catalyzed by MnO 2.
Chemical Kinetics Chapter 14 AP Chemistry.

Chemical Kinetics Chapter 14 AP Chemistry.
Kinetics …or Reaction Rates. Change The ice melted. The Coke went flat. The nail rusted.

Kinetics …or Reaction Rates. Change The ice melted. The Coke went flat. The nail rusted.
Rates and reaction mechanism ► The reaction mechanism is the sequence of individual reaction steps that together complete the transformation of reactants.

Rates and reaction mechanism ► The reaction mechanism is the sequence of individual reaction steps that together complete the transformation of reactants.

Similar presentations

Ads by Google