Chapter 10 Kinetic
Nature of reactants
The temperature
The concentration of reactants
The physical state of reactants
Catalysts
THE RATE EQUATION
k is the rate constant—a constant for each chemical reaction at a given temperature. The exponents m and n, called the orders of reaction,
INTEGRATED RATE LAWS
only cases in which instantaneous data are used in the rate expression have been shown. These expressions allow us to answer questions concerning the speed of the reaction at a particular moment, but not questions about how long it might take to use up a certain reactant, etc.
If changes in the concentration of reactants or products over time are taken into account, as in the integrated rate laws, these questions can be answered.
The Arrhenius equation is most commonly used to calculate the activation energy of a reaction.
The Arrhenius equation has the form: k = Ae-Ea /RT where k is the rate constant, A is a term called the frequency factor that accounts for molecular orientation, e is the natural logarithm base, R is the universal gas constant 8.314 J mol K-1, T is the Kelvin temperature, and Ea is the activation energy,
A + B → C
C + B → D
D → E + F
If you add together the three equations above, you will get the overall equation A + 2B →E + F. C and D are called reaction intermediates, chemical species that are produced and consumed during the reaction, but that do not appear in the overall reaction.
Each individual reaction in the mechanism is called an elementary step or elementary reaction.
One of the reaction steps is slower than the rest and is the rate-determining step.
T is the Kelvin temperature, and Ea is the activation energy, the minimum amount of energy that is needed to initiate or start a chemical reaction.
Many reactions proceed from reactants to products through a sequence of reactions. This sequence of reactions is called the reaction mechanism.
Homogeneous catalysts are catalysts that are in the same phase or state of matter as the reactants. They provide an alternative reaction pathway (a mechanism) with lower activation energy.
The decomposition of hydrogen peroxide is a slow, one-step reaction, especially if the solution is kept cool and in a dark bottle:
2 H2O2 → 2 H2O + O2
However, if ferric ions are added, the reaction speeds up tremendously. The proposed reaction sequence for this new reaction is:
2 Fe3^+ + H2O2 → 2 Fe2^+ + O2 + 2 H^+
2 Fe2^+ + H2O2 + 2 H^+ → 2 Fe3^+ + 2 H2O
A heterogeneous catalyst is in a different phase or state of matter from the reactants.
Most commonly, the catalyst is a solid and the reactants are liquids or gases.
These catalysts lower the activation energy for the reaction by providing a surface for the reaction, and also by providing a better orientation of one reactant so its reactive site is more easily hit by the other reactant
Nature of reactants
The temperature
The concentration of reactants
The physical state of reactants
Catalysts
THE RATE EQUATION
k is the rate constant—a constant for each chemical reaction at a given temperature. The exponents m and n, called the orders of reaction,
INTEGRATED RATE LAWS
only cases in which instantaneous data are used in the rate expression have been shown. These expressions allow us to answer questions concerning the speed of the reaction at a particular moment, but not questions about how long it might take to use up a certain reactant, etc.
If changes in the concentration of reactants or products over time are taken into account, as in the integrated rate laws, these questions can be answered.
The Arrhenius equation is most commonly used to calculate the activation energy of a reaction.
The Arrhenius equation has the form: k = Ae-Ea /RT where k is the rate constant, A is a term called the frequency factor that accounts for molecular orientation, e is the natural logarithm base, R is the universal gas constant 8.314 J mol K-1, T is the Kelvin temperature, and Ea is the activation energy,
A + B → C
C + B → D
D → E + F
If you add together the three equations above, you will get the overall equation A + 2B →E + F. C and D are called reaction intermediates, chemical species that are produced and consumed during the reaction, but that do not appear in the overall reaction.
Each individual reaction in the mechanism is called an elementary step or elementary reaction.
One of the reaction steps is slower than the rest and is the rate-determining step.
T is the Kelvin temperature, and Ea is the activation energy, the minimum amount of energy that is needed to initiate or start a chemical reaction.
Many reactions proceed from reactants to products through a sequence of reactions. This sequence of reactions is called the reaction mechanism.
Homogeneous catalysts are catalysts that are in the same phase or state of matter as the reactants. They provide an alternative reaction pathway (a mechanism) with lower activation energy.
The decomposition of hydrogen peroxide is a slow, one-step reaction, especially if the solution is kept cool and in a dark bottle:
2 H2O2 → 2 H2O + O2
However, if ferric ions are added, the reaction speeds up tremendously. The proposed reaction sequence for this new reaction is:
2 Fe3^+ + H2O2 → 2 Fe2^+ + O2 + 2 H^+
2 Fe2^+ + H2O2 + 2 H^+ → 2 Fe3^+ + 2 H2O
A heterogeneous catalyst is in a different phase or state of matter from the reactants.
Most commonly, the catalyst is a solid and the reactants are liquids or gases.
These catalysts lower the activation energy for the reaction by providing a surface for the reaction, and also by providing a better orientation of one reactant so its reactive site is more easily hit by the other reactant