This is given in the IB data booklet but is useful to know for answering Paper 1 where the data booklet is not allowed.

A has the same units as the rate constant.

Although the correct name for A is the pre-exponential factor it is also known as the frequency constant. Perhaps not surprisingly it is also sometimes called the Arrhenius constant.

It is a rule of thumb that increasing the temperature by 10 K approximately doubles the rate but it is only true when the activation energy is about 50 kJ mol⁻¹ and the temperature rise is from about 298 K to 308 K. For example, if the activation energy is 100 kJ mol⁻¹ and the temperature is increased from 298 K to 308 K the rate nearly quadruples.

Many collisions do not result in a reaction. A is related to the orientation of the collisions as the reactant particles need to collide in a specific way as well as possess the necessary activation energy.

The gradient = −E_a/R so to find E_a the gradient needs to be multiplied by R.

The intercept on the y axis (ln k axis) is equal to ln A.

ln k₁ = − E_a/RT₁ + ln A and ln k₂ = − E_a/RT₂ + ln A
so ln k₁ − ln k₂ = ln k₁/k₂ = − E_a/RT₁ − (− E_a/RT₂) = E_a/R x (1/T₂− 1/T₁)
ln k₁/k₂ = E_a/R x (1/1000 − 1/500) = −0.001 x E_a/R

At 27 ^oC without a catalyst the number of particles with an energy equal to or greater than E_a = e^{−(60 x 1000)/(R x 300)}
At 27 ^oC with a catalyst the number of particles with an energy equal to or greater than E_a = e^{−(40 x 1000)/(R x 300)}
The number has therefore increased by e^{−(40 x 1000)/(R x 300)} ÷ e^{−(60 x 1000)/(R x 300)}. E_a must be multiplied by 1000 as the units of R are J K⁻¹ mol⁻¹.

The Arrhenius equation applies to all chemical reactions whether they are exothermic or endothermic. It will not work for some reactions above certain temperatures where one or more of the reactants decomposes before it can react, e.g. enzyme catalysed reactions.