(Redirected from Nernst\'s theorem)
The 'third law of
thermodynamics' is an axiom of nature regarding
entropy and the impossibility of reaching
absolute zero of
temperature. The most common enunciation of third law of thermodynamics is:
The essence of the postulate is that the entropy of the given system near absolute zero depends only on the temperature (i.e. tends to a constant ''independently'' of the other parameters).
History
The third law was developed by
Walther Nernst, during the years 1906-1912, and is thus sometimes referred to as 'Nernst's theorem' or 'Nernst's postulate'. The third law of thermodynamics states that the
entropy of a system at
zero is a well-defined constant. This is because a system at zero temperature exists in its
ground state, so that its entropy is determined only by the
degeneracy of the ground state; or, it states that "''it is impossible by any procedure, no matter how idealised, to reduce any system to the absolute zero of temperature in a finite number of operations''".
An alternative version of the third law of thermodynamics as stated by
Gilbert N. Lewis and
Merle Randall in 1923:
This version states not only ΔS will reach zero at T = 0 K, but S itself will also reach zero.
Overview
In simple terms, the Third Law states that the entropy of a pure substance approaches zero as the absolute temperature approaches zero. This law provides an absolute reference point for the determination of entropy. The entropy determined relative to this point is the absolute entropy.
A special case of this is systems with a unique ground state, such as
crystal lattices. The entropy of a ''perfect'' crystal lattice as defined by Nernst's theorem is zero (since log(1) = 0).The only systems which do not have a unique ground state are those with half-integer
spin, for which
time-reversal symmetry gives two degenerate ground states. Of course, this entropy is negligible on a macroscopic scale.
Real crystals with frozen defects obey this same law, so long as one considers a particular defect configuration to be fixed. The defects would not be present in thermal equilibrium, so if one considers a collection of different possible defects, the collection would have some entropy, but not actually have a temperature. Such considerations become more interesting and problematic in considering various forms of
glass, since glasses have large collections of nearly degenerate states, in which they become trapped out of equilibrium.
Another application of the third law is with respect to the magnetic moments of a material. Paramagnetic materials (moments random) will order as T approaches 0 K. They may order in a ferromagnetic sense, with all moments parallel to each other, or they may order in an antiferromagnetic sense, with all moments antiparallel to each other.
Yet another application of the third law is the fact that at 0 K no solid solutions should exist. Phases in equilibrium at 0 K should either be pure elements or atomically ordered phases.
[1]
See also
★
Adiabatic process
★
Ground state
★
Laws of thermodynamics
★
Thermodynamic entropy
★
Thermodynamics
★
Timeline of thermodynamics, statistical mechanics, and random processes
References
1. Abriata, J.P. and Laughlin, D.E. (2004) “The Third Law of Thermodynamics and low temperature phase stability,” ''Progress in Materials Science 49'', 367-387, .
Further reading
★ Goldstein, Martin, and Inge F., 1993. ''The Refrigerator and the Universe''. Harvard Univ. Press. Chpt. 14 discusses the Third Law. Overall, a gentle introduction to thermodynamics.
External links
★
20+ Variations of the 3rd Law
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