Respuesta :
Answer:
The activation energy is [tex]=8.1\,kcal\,mol^{-1}[/tex]
Explanation:
The gas phase reaction is as follows.
[tex]A \rightarrow B+C[/tex]
The rate law of the reaction is as follows.
[tex]-r_{A}=kC_{A}[/tex]
The reaction is carried out first in the plug flow reactor with feed as pure reactant.
From the given,
Volume "V" = [tex]10dm^{3}[/tex]
Temperature "T" = 300 K
Volumetric flow rate of the reaction [tex]v_{o}=5dm^{3}s[/tex]
Conversion of the reaction "X" = 0.8
The rate constant of the reaction can be calculate by the following formua.
[tex]V= \frac{v_{0}}{k}[(1+\epsilon )ln(\frac{1}{1-X}-\epsilon X)][/tex]
Rearrange the formula is as follows.
[tex]k= \frac{v_{0}}{V}[(1+\epsilon )ln(\frac{1}{1-X}-\epsilon X)]............(1)[/tex]
The feed has Pure A, mole fraction of A in feed [tex]y_{A_{o}}[/tex] is 1.
[tex]\epsilon =y_{A_{o}}\delta[/tex]
[tex]\delta[/tex] = change in total number of moles per mole of A reacte.
[tex]=1(2-1)=1[/tex]
Substitute the all given values in equation (1)
[tex]k=\frac{5m^{3}/s}{10dm^{3}}[(1+1)ln \frac{1}{1-0.8}-1 \times 0.8] = 1.2s^{-1}[/tex]
Therefore, the rate constant in case of the plug flow reacor at 300K is[tex]1.2s^{-1}[/tex]
The rate constant in case of the CSTR can be calculated by using the formula.
[tex]\frac{V}{v_{0}}= \frac{X(1+\epsilon X)}{k(1-X)}.............(2)[/tex]
The feed has 50% A and 50% inerts.
Hence, the mole fraction of A in feed [tex]y_{A_{o}}[/tex] is 0.5
[tex]\epsilon =y_{A_{o}}\delta[/tex]
[tex]\delta[/tex] = change in total number of moles per mole of A reacted.
[tex]=0.5(2-1)=0.5[/tex]
Substitute the all values in formula (2)
[tex]\frac{10dm^{3}}{5dm^{3}}=\frac{0.8(1+0.5(0.8))}{k(1-0.8)}=2.8s^{-1}[/tex]
Therefore, the rate constant in case of CSTR comes out to be [tex]2.8s^{-1}[/tex]
The activation energy of the reaction can be calculated by using formula
[tex]k(T_{2})=k(T_{1})exp[\frac{E}{R}(\frac{1}{T_{1}}-\frac{1}{T_{2}})][/tex]
In the above reaction rate constant at the two different temperatures.
Rearrange the above formula is as follows.
[tex]E= R \times(\frac{T_{1}T_{2}}{T_{1}-T_{2}})ln\frac{k(T_{2})}{k(T_{1})}[/tex]
Substitute the all values.
[tex]=1.987cal/molK(\frac{300K \times320K}{320K \times300K})ln \frac{2.8}{1.2}=8.081 \times10^{3}cal\,mol^{-1}[/tex]
[tex]=8.1\,kcal\,mol^{-1}[/tex]
Therefore, the activation energy is [tex]=8.1\,kcal\,mol^{-1}[/tex]
