The Arrhenius Equation (College Board AP® Chemistry)
Study Guide
Written by: Oluwapelumi Kolawole
Reviewed by: Stewart Hird
The Arrhenius Equation
The effect of temperature on reaction rate can be explained in terms of kinetic theory
Increasing temperature greatly increases the fraction of molecules with very high velocity and high kinetic energies
These molecules are more likely to react on collision and produce enough energy equal to or greater than the activation energy
Hence, the higher the temperature, the larger the fraction of molecules that can provide the activation energy required for reaction
Based on the collision model, the rate constant for an elementary reaction was given as
k = p × Z × f (equation 1)
Where:
Z, the collision frequency
f, the fraction of collisions p, the steric factor
The steric factor, p, is presumably temperature-independent
The collision frequency, Z, is relatively insensitive to temperature
For example, when the temperature increases from 500 to 600 K, Z increases by less than 10%
On the other hand, the relationship between the fraction of collisions with energy greater than the activation energy and temperature has been shown as:
f = e-Ea/RT (equation 2)
Where:
e is a mathematical constant (can be found on your calculator - it has the approximate value of 2.718
Ea is activation energy measured in J/mol
R is the gas constant (8.314 Jmol-1K-1)
T is the absolute temperature in K
A combination of equations 1 and 2 gives the Arrhenius equation, which shows how the rate constant is dependent on temperature
k = Ae-Ea/RT
Where A is a constant and called the frequency factor
This factor is related to the frequency of collisions, Z and the steric factor, p
In general, as the value of Ea increases, k decreases
This is because the fraction of molecules that possess the required energy is smaller
On taking the natural log of both sides of the Arrhenius equation, the equation becomes:
ln k = ln A - Ea/RT
A plot of ln k against 1/T gives a straight line with a negative slope:
Arrhenius’s Plot
Graph showing the relationship between absolute temperature and the rate constant of a reaction
Examiner Tips and Tricks
Although calculations involving Arrhenius’s equation will not be assessed this year (2024), it is important to take note of the relationship between rate constant, activation energy and temperature of a reaction
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