Statistical physics of directional, stochastic chains with memory

J. Ricardo Arias-Gonzalez

Published 2015-11-19Version 1

Stochastic chains represent a wide and key variety of phenomena in many branches of science within the context of Information Theory and Thermodynamics. They are typically approached by a sequence of independent events or by a memoryless Markov process. Here, we demonstrate that when memory is introduced, the statistics of the system depends on the mechanism by which objects or symbols are assembled, even in the slow dynamics limit wherein friction can be neglected. To analyse these systems, we introduce a sequence-dependent partition function, investigate its properties and compare it to the standard normalization defined by the statistical physics of ensembles. Then, we study the behaviour of the entropy and the internal energy in this intrinsic, directional chains finding that they vary around their thermally-induced equilibrium analogues due to memory effects. We anticipate that our results are necessary to interpret configurational order and information transfer in many molecular systems within Materials Science, Biophysics, Communication and Engineering.