Percent change in thermionic emission

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benben312000
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% change in thermionic emission

Q1. Determine the % change in thermionic emission for an oxide-coated filament of work function of 1.3eV if the temperature is decreased by 1.00% at a temperature of 2300K

I'm uncertain but i used

dJ/J=dT/T ( 2 + ((1160x1.3)/1000)

to get a 15% change in current density. I'm not really good at this so i not sure if i used the formula correctly

Q2. Calculate the % change in therimonic amission from tungsten filament of work function 4.52eV if the work funtion is decreased by 1.00% at a temperature of 2300K

I was really puzzled by this question as the difference is in this question the work function is said to decrease but i do not know how to calculate the % change.

Thanks in advance for all the help given.
 
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Use the old (1901, Richardson) formula for thermionic emission:
J = K(T^2)exp(-W/kT),

J = thermionic current density
K = constant peculiar to emitting oxide,
W = work function of oxide
T = temperature, Kelvin.
 


Thanks lots Rude man o:)

Hmm that's interesting i came across a Richardson-Dushmann law as well but it's not so similar, but that's how i get the "dJ/J=dT/T ( 2 + ((1160x1.3)/1000)". But it's differentiate with respect to the absolute temperature.

Btw do u mean i could use the same formula for both the question cause i don't understand the 2nd question.

Thanks once again
 


benben312000 said:
Thanks lots Rude man o:)

Hmm that's interesting i came across a Richardson-Dushmann law as well but it's not so similar, but that's how i get the "dJ/J=dT/T ( 2 + ((1160x1.3)/1000)". But it's differentiate with respect to the absolute temperature.

Btw do u mean i could use the same formula for both the question cause i don't understand the 2nd question.

Thanks once again

Yes, the formula isused for both of your questions. Just need a bit of calculus:

dJ/J = (1/J)∂J/∂T*dT + (1/J)∂J/∂W*dW

For your 1st problem, W is constant.
For your 2nd problem, T is constant.
Away you go!

PS - from Wikipedia: "Over 60 years later, there is still no consensus amongst interested theoreticians as to what the precise form of the expression for K should be ... "

PPS - for you that makes no difference since K will cancel out when you divide by J.
 
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