LOW-TEMPERATURE ISING DYNAMICS WITH RANDOM INITIALIZATIONS
成果类型:
Article
署名作者:
Gheissari, Reza; Sinclair, Alistair
署名单位:
University of California System; University of California Berkeley; University of California System; University of California Berkeley; University of California System; University of California Berkeley
刊物名称:
ANNALS OF APPLIED PROBABILITY
ISSN/ISSBN:
1050-5164
DOI:
10.1214/22-AAP1911
发表日期:
2023
页码:
3916-3957
关键词:
random-cluster dynamics
order large deviations
glauber dynamics
boundary-conditions
swendsen-wang
MODEL
coexistence
percolation
cutoff
potts
摘要:
It is well known that Glauber dynamics on spin systems typically suffer exponential slowdowns at low temperatures. This is due to the emergence of multiple metastable phases in the state space, separated by narrow bottle-necks that are hard for the dynamics to cross. It is a folklore belief that if the dynamics is initialized from an appropriate random mixture of ground states, one for each phase, then convergence to the Gibbs distribution should be much faster. However, such phenomena have largely evaded rigorous analysis, as most tools in the study of Markov chain mixing times are tailored to worst-case initializations.In this paper we develop a general framework towards establishing this conjectured behavior for the Ising model. In the classical setting of the Ising model on an N-vertex torus in Zd, our framework implies that the mixing time for the Glauber dynamics, initialized from a 21- 2 1 mixture of the all -plus and all-minus configurations, is N1+o(1) in dimension d = 2, and at most quasi-polynomial in all dimensions d >= 3, at all temperatures below the critical one. The key innovation in our analysis is the introduction of the notion of weak spatial mixing within a phase, a low-temperature adaptation of the classical concept of weak spatial mixing. We show both that this new notion is strong enough to control the mixing time from the above random initialization (by relating it to the mixing time with plus boundary condition at O (log N) scales), and that it holds at all low temperatures in all dimensions. This framework naturally extends to more general families of graphs. To illustrate this, we use the same approach to establish optimal O (N log N) mixing for the Ising Glauber dynamics on random regular graphs at sufficiently low temperatures, when initialized from the same random mixture.
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