English

Non-compact quantum spin chains as integrable stochastic particle processes

Mathematical Physics 2024-05-31 v5 Statistical Mechanics High Energy Physics - Theory math.MP Probability

Abstract

In this paper we discuss a family of models of particle and energy diffusion on a one-dimensional lattice, related to those studied previously in [Sasamoto-Wadati], [Barraquand-Corwin] and [Povolotsky] in the context of KPZ universality class. We show that they may be mapped onto an integrable sl(2)\mathfrak{sl}(2) Heisenberg spin chain whose Hamiltonian density in the bulk has been already studied in the AdS/CFT and the integrable system literature. Using the quantum inverse scattering method, we study various new aspects, in particular we identify boundary terms, modeling reservoirs in non-equilibrium statistical mechanics models, for which the spin chain (and thus also the stochastic process) continues to be integrable. We also show how the construction of a "dual model" of probability theory is possible and useful. The fluctuating hydrodynamics of our stochastic model corresponds to the semiclassical evolution of a string that derives from correlation functions of local gauge invariant operators of N=4\mathcal{N}=4 super Yang-Mills theory (SYM), in imaginary-time. As any stochastic system, it has a supersymmetric completion that encodes for the thermal equilibrium theorems: we show that in this case it is equivalent to the sl(21)\mathfrak{sl}(2|1) superstring that has been derived directly from N=4\mathcal{N}=4 SYM.

Keywords

Cite

@article{arxiv.1904.01048,
  title  = {Non-compact quantum spin chains as integrable stochastic particle processes},
  author = {Rouven Frassek and Cristian Giardinà and Jorge Kurchan},
  journal= {arXiv preprint arXiv:1904.01048},
  year   = {2024}
}

Comments

35 pages, 2 figures, v2: typos fixed and references added, v3: typo fixed, v4,5: minor correction

R2 v1 2026-06-23T08:25:56.363Z