The derivation of the Thiele Modulus (from Hill) begins with a material balance on the catalyst pore. For a first-order irreversible reaction in a straight cylindrical pore at steady state:

${\displaystyle {\pi }r^{2}\left(-D_{c}{\frac {dC}{dx}}\right)_{x}={\pi }r^{2}\left(-D_{c}{\frac {dC}{dx}}\right)_{x+{\Delta }x}+\left(2{\pi }r{\Delta }x\right)\left(k_{1}C\right)}$ 

where ${\displaystyle D_{c}}$  is a diffusivity constant, and ${\displaystyle k_{1}}$  is the rate constant.

Then, turning the equation into a differential by dividing by ${\displaystyle {\Delta }x}$  and taking the limit as ${\displaystyle {\Delta }x}$  approaches 0,

${\displaystyle D_{c}\left({\frac {d^{2}C}{dx^{2}}}\right)={\frac {2k_{1}C}{r}}}$ 

This differential equation with the following boundary conditions:

${\displaystyle C=C_{o}{\text{ at }}x=0}$ 

and

${\displaystyle {\frac {dC}{dx}}=0{\text{ at }}x=L}$ 

where the first boundary condition indicates a constant external concentration on one end of the pore and the second boundary condition indicates that there is no flow out of the other end of the pore.

Plugging in these boundary conditions, we have

${\displaystyle {\frac {d^{2}C}{d(x/L)^{2}}}=\left({\frac {2k_{1}L^{2}}{rD_{c}}}\right)C}$ 

The term on the right side multiplied by C represents the square of the Thiele Modulus, which we now see rises naturally out of the material balance. Then the Thiele modulus for a first order reaction is:

${\displaystyle h_{T}^{2}={\frac {2k_{1}L^{2}}{rD_{c}}}}$ 

From this relation it is evident that with large values of ${\displaystyle h_{T}}$ , the rate term dominates and the reaction is fast, while slow diffusion limits the overall rate. Smaller values of the Thiele modulus represent slow reactions with fast diffusion.

Other order reactions may be solved in a similar manner as above. The results are listed below for irreversible reactions in straight cylindrical pores.

Second order Reaction edit

${\displaystyle h_{2}^{2}={\frac {2L^{2}k_{2}C_{o}}{rD_{c}}}}$ 

Zero order reaction edit

${\displaystyle h_{o}^{2}={\frac {2L^{2}k_{o}}{rD_{c}C_{o}}}}$ 

Effectiveness Factor edit

The effectiveness factor η relates the diffusive reaction rate with the rate of reaction in the bulk stream.

For a first order reaction in a slab geometry,^[1][3] this is:

${\displaystyle {\eta }={\frac {\tanh h_{T}}{h_{T}}}}$