Answer:
T=575.16K
Explanation:
To solve the problem we proceed to use the 1 law of diffusion of flow,
Here,
[tex]J=-D\frac{\Delta C}{\Delta x}[/tex]
[tex]\Delta C[/tex] is the rate in concentration
[tex]\Delta x[/tex]is the rate in thickness
D is the diffusion coefficient, where,
[tex]D= D_0 exp(\frac{Q_d}{RT})[/tex]
Replacing D in the first law,
[tex]J=-(D_0 exp(\frac{-Q_D}{RT}))\frac{\Delta }{\Delta x}[/tex]
clearing T,
[tex]T=\frac{Q_d}{R*ln(\frac{J*\Delta x}{D_0*\Delta C})}[/tex]
Replacing our values
[tex]T=-\frac{80000}{8.31*ln(\frac{(6.2*10^{-7})(-15*10^{-3})}{(1.43*10^{-9})(0.65-0.30)})}[/tex]
[tex]T=-\frac{80000}{-138.09}[/tex]
[tex]T=575.16K[/tex]
