# A general renormalization procedure on the one-dimensional lattice and   decay of correlations

**Authors:** Artur O. Lopes

arXiv: 1701.07656 · 2017-12-13

## TL;DR

This paper introduces a general renormalization operator on one-dimensional lattice potentials, finds its fixed point, and analyzes the decay of correlations, revealing polynomial and faster decay rates for a broad class of potentials.

## Contribution

It generalizes previous fixed point results to a wider class of potentials and provides explicit decay estimates for correlations in these systems.

## Key findings

- Fixed point potential expressed via Hausdorff measure on a Cantor set
- Decay of correlations can be polynomial or faster than exponential
- Explicit construction of potentials with prescribed correlation decay

## Abstract

We present a general form of Renormalization operator $\mathcal{R}$ acting on potentials $V:\{0,1\}^\mathbb{N} \to \mathbb{R}$. We exhibit the analytical expression of the fixed point potential $V$ for such operator $\mathcal{R}$. This potential can be expressed in a naturally way in terms of a certain integral over the Hausdorff probability on a Cantor type set on the interval $[0,1]$. This result generalizes a previous one by A. Baraviera, R. Leplaideur and A. Lopes where the fixed point potential $V$ was of Hofbauer type.   For the potentials of Hofbauer type (a well known case of phase transition) the decay is like $n^{-\gamma}$, $\gamma>0$.   Among other things we present the estimation of the decay of correlation of the equilibrium probability associated to the fixed potential $V$ of our general renormalization procedure. In some cases we get polynomial decay like $n^{-\gamma}$, $\gamma>0$, and in others a decay faster than $n \,e^{ -\, \sqrt{n}}$, when $n \to \infty$.   The potentials $g$ we consider here are elements of the so called family of Walters potentials on $\{0,1\}^\mathbb{N} $ which generalizes the potentials considered initially by F. Hofbauer. For these potentials some explicit expressions for the eigenfunctions are known.   In a final section we also show that given any choice $d_n \to 0$ of real numbers varying with $n \in \mathbb{N}$ there exist a potential $g$ on the class defined by Walters which has a invariant probability with such numbers as the coefficients of correlation (for a certain explicit observable function).

## Full text

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## References

29 references — full list in the complete paper: https://tomesphere.com/paper/1701.07656/full.md

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Source: https://tomesphere.com/paper/1701.07656