- Nernst heat theorem: In the neighborhood of absolute zero, all reactions in a liquid or solid
- in internal equilibrium take place with no change in entropy.
- (consider e.g. a chemical reaction )
- Motivated by considering reactions in the limit of decreasing temperature
- We know: at P, T=const. equilibrium thermodynamics determined by Gmin.
- (see thermodynamic potentials)
- Nernst proposed as a general principle:
- heat flow into bath (exotherm)
- but sometimes also
- out of the bath (endotherm)
- Planck made further hypothesis known as the third law
- Some consequences of the third law
- It is impossible to reach the absolute zero temperature
- with a finite sequence of isothermal and adiabatic changes of pressure or other
- variables like the magnetic field, e.g., in the case of adiabatic demagnetization.
- Gas compression refrigeration
- T=0 not achievable in a finite # of
- compression and expansion steps
- W: # of possible microstates
- Although we don’t focus on stat. mechanics it is useful to get an idea how the third law is related to the Boltzmann formula
- energy-eigenvalues having a lower bound (ground state):
- @ sufficient low T system will be in its ground state
- If there are g0 eigenstates with the same energy E0 we say ground state is degenerate
- # of microstates representing the same macro state is W=g0 and, hence
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