This article includes a
list of references,
related reading, or
external links, but its sources remain unclear because it lacks
inline citations. (December 2023) |
The Helmholtz theorem of classical mechanics reads as follows:
Let
Then
The thesis of this theorem of
classical mechanics reads exactly as the
heat theorem of
thermodynamics. This fact shows that thermodynamic-like relations exist between certain mechanical quantities. This in turn allows to define the "thermodynamic state" of a one-dimensional mechanical system. In particular the
temperature is given by time average of the kinetic energy, and the
entropy by the logarithm of the
action (i.e., ).
The importance of this theorem has been recognized by
Ludwig Boltzmann who saw how to apply it to macroscopic systems (i.e. multidimensional systems), in order to provide a mechanical foundation of
equilibrium thermodynamics. This research activity was strictly related to his formulation of the
ergodic hypothesis.
A multidimensional version of the Helmholtz theorem, based on the
ergodic theorem of
George David Birkhoff is known as generalized Helmholtz theorem.
The generalized Helmholtz theorem is the multi-dimensional generalization of the Helmholtz theorem, and reads as follows.
Let
be the canonical coordinates of a s-dimensional Hamiltonian system, and let
be the Hamiltonian function, where
is the kinetic energy and
is the potential energy which depends on a parameter . Let the hyper-surfaces of constant energy in the 2s-dimensional phase space of the system be metrically indecomposable and let denote time average. Define the quantities , , , , as follows:
Then:
This article includes a
list of references,
related reading, or
external links, but its sources remain unclear because it lacks
inline citations. (December 2023) |
The Helmholtz theorem of classical mechanics reads as follows:
Let
Then
The thesis of this theorem of
classical mechanics reads exactly as the
heat theorem of
thermodynamics. This fact shows that thermodynamic-like relations exist between certain mechanical quantities. This in turn allows to define the "thermodynamic state" of a one-dimensional mechanical system. In particular the
temperature is given by time average of the kinetic energy, and the
entropy by the logarithm of the
action (i.e., ).
The importance of this theorem has been recognized by
Ludwig Boltzmann who saw how to apply it to macroscopic systems (i.e. multidimensional systems), in order to provide a mechanical foundation of
equilibrium thermodynamics. This research activity was strictly related to his formulation of the
ergodic hypothesis.
A multidimensional version of the Helmholtz theorem, based on the
ergodic theorem of
George David Birkhoff is known as generalized Helmholtz theorem.
The generalized Helmholtz theorem is the multi-dimensional generalization of the Helmholtz theorem, and reads as follows.
Let
be the canonical coordinates of a s-dimensional Hamiltonian system, and let
be the Hamiltonian function, where
is the kinetic energy and
is the potential energy which depends on a parameter . Let the hyper-surfaces of constant energy in the 2s-dimensional phase space of the system be metrically indecomposable and let denote time average. Define the quantities , , , , as follows:
Then: