Open AccessPrinciples of time evolution in classical physics
Author(s) -
J. Güémez,
M. Fiolhais
Publication year - 2018
Publication title -
european journal of physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.421
H-Index - 51
eISSN - 1361-6404
pISSN - 0143-0807
DOI - 10.1088/1361-6404/aabbfb
Subject(s) - physics , dissipative system , dissipation , classical mechanics , conservation of energy , time evolution , hamiltonian (control theory) , internal energy , time derivative , entropy (arrow of time) , work (physics) , entropy production , conservative force , mechanical energy , mechanical system , arrow of time , second law of thermodynamics , statistical physics , theoretical physics , quantum mechanics , mathematical optimization , power (physics) , mathematics , artificial intelligence , computer science , quantum
We address principles of time evolution in classical mechanical/thermodynamical systems in translational and rotational motion, in three cases: when there is conservation of mechanical energy, when there is energy dissipation and when there is mechanical energy production. In the first case, the time derivative of the Hamiltonian vanishes. In the second one, when dissipative forces are present, the time evolution is governed by the minimum potential energy principle, or, equivalently, maximum increase of the entropy of the universe. Finally, in the third situation, when internal sources of work are available to the system, it evolves in time according to the principle of minimum Gibbs function. We apply the Lagrangian formulation to the systems, dealing with the non-conservative forces using restriction functions such as the Rayleigh dissipative function.
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