1. Rate Expression and reaction mechanism

2. Rate Law
Concentration of reactants and rate of reaction – as the concentration of any of the reactants change, the rate of the reaction changes.
The Rate law for a reaction describes how the rate of the reaction depends on the concentration of the reactants.
For the reaction
Where, k is called the rate constant at a particular temperature. The exponents, x and y, and the rate constant bear no necessary relationship to the coefficients of the balanced chemical equation; they must be determined experimentally.

3. Rate law
The exponents are usually positive integers, or zero, but they can occasionally be a fraction or a negative number.
For the above rate law,

4. remember

7. Units of the rate constant (k)
The units of the rate constant depend on the overall order of the reaction.

11. Graphical Representations of Reaction Kinetics
Rate vs. Concentration graphs show the difference between zero order, first order, and second order reactions.

12. Zero-order reactions
In zero order reactions, the concentration of the reactants does not affect the rate of the reaction, so the rate-concentration graph is a horizontal line

13. First-order reactions
In first order reactions, the rate is directly proportional to the concentration of A. The rate-concentration graph is a straight line that passes through the origin.

14. Second-order reactions
In a second order reaction, the rate is proportional to the square of the concentration of A. /so, the rate-concentration graph is a parabola.

15. First order reactions have a constant half-life
Concentration vs. time graphs for first order reactions show that the time it takes for the concentration of the reactant to decrease by half of its original value is independent of the starting concentration. The time it takes for half the sample to react is known as the half-life and it is constant for first order reactions.

16. Determining the order of the reaction
The order of the reaction can be determined by the initial rates method.
This method involves carrying out separate experiments where the concentration of one of the reactants is kept constant while the concentration of the other reactant is changed.
The process is then repeated changing the concentration of the other reactant while keeping the concentration of the first reactant constant.

24. Reaction Mechanisms
A reaction mechanism is the step-by step pathway by which a reaction occurs.
Some reactions take place in a single step, however, most reactions occur in a series of elementary steps.
Evidence can support a reaction mechanism, but it cannot prove it to be correct- only that it is consistent with the observed data.

25. Reaction Mechanisms For each of these elementary steps:
the order for the reactants in any single elementary step is equal to its coefficient.
Note: the rate law exponents do not necessarily match those of the coefficients of the overall balanced equation.
2. There is an elementary step that is much slower than the others. This slow step is called the rate-determining step. The speed at which the rate-determining step occurs limits the rate at which the overall reaction takes place. Fast steps occurring after the rate determining step have no effect on the rate law.

27. Reaction Mechanisms
The sum of all the elementary steps is equal to the balanced equation for the overall reaction.
Species that are formed and that are consumed are called intermediates. Intermediates on both sides cancel out.

28. Reaction Mechanisms
The term that describes the number of molecules reacting is called the molecularity of a reaction. Most elementary steps are unimolecular (only one reactant participates) or bimolecular (two reactants participate). There are very few termolecular reactions.

29. Reaction mechanisms
The rate expression for an overall reaction is determined by the reaction mechanism.
If the rate-determining step is the first step in the mechanism, or the only step, then its rate law is the same as the rate expression for the overall reaction.

30. Reaction mechanisms

31. When the rate-determining step is not the first step in the mechanism, it is necessary to take into account the earlier steps.