Thermodynamics, Statistical Physics, and Quantum Mechanics

(Axel Boer) #1
89

4.6 Teacup Engine (Princeton, Moscow Phys-Tech)


If the cup were vacuumtight, the number of molecules leaving the surface
would be the same as the number of molecules returning to the surface.
The mass flow rate of the molecules hitting the surface (see Problem 4.14)
is

where is the vapor density corresponding to the saturation, is the
average velocity of the molecules, and A is the surface area of the ice. The
mass flow rate of the molecules actually returning to the surface is

where is the stickingcoefficient(the probabilitythat themoleculehitting
the surface will stick to it). Let us assume for now that (we will
see later that this is not true, but that actually gives us the lower limit
of the distance). If the cup is open we can assume that the number of
molecules leaving the surface is the same as in the closed cup, but there
are few returning molecules. We then find that the time for complete
evaporation of the ice is

where we take g as the mass of the ice, and


from Problem 4.13. Substituting (S.4.6.4) into (S.4.6.3), we obtain

Once again using the ideal gas law, we may obtain

Substituting(S.4.6.6) into(S.4.6.5) yields


THERMODYNAMICS AND STATISTICAL PHYSICS
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