Relating the thermodynamic arrow of time to the causal arrow

Armen E Allahverdyan; Balian R; Becker R; Berdichevsky V L; Berry M V; Campisi M; Carroll S M Chen J; Carroll S M Chen J; De Roeck W Maes C Netocny K; Dominik Janzing; Gemmer J; Gorban A; Haken H; Hoffding H; Kano Y Shimizu S; Kasuga T; Lichtenberg A J; Lindblad G; Munster A; Pearl J; Penrose O; Reichenbach H; Risken H; Sagdeev R Z; Schulman L S; Schölkopf B; Spirtes P; Sun X Janzing D Schölkopf B; Wald R M; Weiss U; Zeh H D

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Relating the thermodynamic arrow of time to the causal arrow

Authors: Armen E Allahverdyan
Balian R
Becker R
Berdichevsky V L
Berry M V
Campisi M
Carroll S M Chen J
Carroll S M Chen J
De Roeck W Maes C Netocny K
Dominik Janzing
Gemmer J
Gorban A
Haken H
Hoffding H
Kano Y Shimizu S
Kasuga T
Lichtenberg A J
Lindblad G
Munster A
Pearl J
Penrose O
Reichenbach H
Risken H
Sagdeev R Z
Schulman L S
Schölkopf B
Spirtes P
Sun X Janzing D Schölkopf B
Wald R M
Weiss U
Zeh H D
Publication date: 8 August 2007
Publisher: 'IOP Publishing'
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Abstract

Consider a Hamiltonian system that consists of a slow subsystem S and a fast subsystem F. The autonomous dynamics of S is driven by an effective Hamiltonian, but its thermodynamics is unexpected. We show that a well-defined thermodynamic arrow of time (second law) emerges for S whenever there is a well-defined causal arrow from S to F and the back-action is negligible. This is because the back-action of F on S is described by a non-globally Hamiltonian Born-Oppenheimer term that violates the Liouville theorem, and makes the second law inapplicable to S. If S and F are mixing, under the causal arrow condition they are described by microcanonic distributions P(S) and P(S|F). Their structure supports a causal inference principle proposed recently in machine learning.Comment: 10 page

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