English

Reconstructing Equilibrium Entropy and Enthalpy Profiles from Non-equilibrium Pulling

Statistical Mechanics 2015-06-11 v2 Soft Condensed Matter Biological Physics

Abstract

The Jarzynski identity can be applied to instances when a microscopic system is pulled repeatedly but quickly along some coordinate, allowing the calculation of an equilibrium free energy profile along the pulling coordinate from a set of independent non-equilibrium trajectories. Using the formalism of Wiener stochastic path integrals in which we assign temperature-dependent weights to Langevin trajectories, we derive exact formulae for the temperature derivatives of the free energy profile. This leads naturally to analytical expressions for decomposing a free energy profile into equilibrium entropy and internal energy profiles from non-equilibrium pulling. This decomposition can be done from trajectories evolved at a unique temperature without repeating the measurement as done in finite-difference decompositions. Three distinct analytical expressions for the entropy-energy decomposition are derived: using a time-dependent generalization of the weighted histogram analysis method, a quasi harmonic spring limit, and a Feynman-Kac formula. The three novel formulae of reconstructing the pair of entropy-energy profiles are exemplified by Langevin simulations of a two-dimensional model system prototypical for force-induced biomolecular conformational changes. Connections to single-molecule experimental means to probe the functionals needed in the decomposition are suggested.

Keywords

Cite

@article{arxiv.1210.5793,
  title  = {Reconstructing Equilibrium Entropy and Enthalpy Profiles from Non-equilibrium Pulling},
  author = {Daun Jeong and Ioan Andricioaei},
  journal= {arXiv preprint arXiv:1210.5793},
  year   = {2015}
}
R2 v1 2026-06-21T22:25:33.274Z