How Do You Derive Particle Distributions Using the Boltzmann Factor?

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ferret123
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Homework Statement



A system in thermal equilibrium at temperature T consists of N particles that have two
energy states separated by an energy Δε.

If the number of particles in the two states is N1 and N2, show that:

[itex]N{1}[/itex] = N([itex]\frac{1}{1+exp(-Δε/k{B}T}[/itex])) and [itex]N{2}[/itex] = N([itex]\frac{exp(-Δε/k{B}T}{1+exp(-Δε/k{B}T}[/itex]))

Homework Equations


[itex]\frac{N{1}}{N{2}}[/itex] = [itex]\frac{exp(-E{1}/k{B}T}{exp(-E{2}/k{B}T}[/itex]

Δε=E1 - E2


The Attempt at a Solution



Really struggling to see where to get started with this the lectures and the lecture notes we have are not helping.
 
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ferret123 said:

Homework Equations


[itex]\frac{N{1}}{N{2}}[/itex] = [itex]\frac{exp(-E{1}/k{B}T)}{exp(-E{2}/k{B}T)}[/itex]

Δε=E1 - E2

From the way the problem is worded, I think Δε should be Δε = E2 - E1

See if you can show [itex]\frac{N{2}}{N{1}}= {exp(-Δε/k_{B}T)}[/itex]

Also, what must the sum N1+N2 equal?
 
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Well N1 + N2 must equal N?

So now that I have it in terms of Δε I can rearrange for expressions for N1 and N2 then add them for N?