Finding the equation of the adiabats.

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Working from Callen, Chapter 1:

Find the equation of the adiabats in the P-V plane given
<br /> U = AP^2V<br />

Where A is defined as a positive constant of dimension [P]^-1.

I'm not sure what to do with this. I was thinking of solving the equation for P and then...no idea.

If I do that I (probably incorrectly) get something like this:

<br /> P = \frac{U}{V}<br />

After plopping this into Mathematica I can see that it looks like an adiabatic curve, but there's no way the problem is that easy. So I think I'm not going about this correctly. Just looking for some pointers/guidance.

Thanks.
 
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The equation of the adiabats in the P-V plane can be found by rearranging the given equation to solve for V, resulting in the equation:V = \frac{U}{AP^2}This equation describes the relationship between Pressure (P) and Volume (V) and is the equation of the adiabats in the P-V plane.
 

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