Invisibility of the integers for the discrete Gaussian chain via a Caffarelli-Silvestre extension of the discrete fractional Laplacian

arXiv - PHYS - Mathematical Physics Pub Date : 2023-12-07 DOI:arxiv-2312.04536

Christophe Garban

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Abstract

The Discrete Gaussian Chain is a model of interfaces $\Psi : \mathbf{Z} \to \mathbf{Z}$ governed by the Hamiltonian $$ H(\Psi)= \sum_{i\neq j} J_\alpha(|i-j|) |\Psi_i -\Psi_j|^2 $$ with long-range coupling constants $J_\alpha(k)\asymp k^{-\alpha}$. For any $\alpha\in [2,3)$ and at high enough temperature, we prove an invariance principle for such an $\alpha$-Discrete Gaussian Chain towards a $H(\alpha)$-fractional Gaussian process where the Hurst index $H$ satisfies $H=H(\alpha)=\frac {\alpha-2} 2$. This result goes beyond a conjecture by Fr\"ohlich and Zegarlinski \cite{frohlich1991phase} which conjectured fluctuations of order $n^{\tfrac 1 2 (\alpha-2) \wedge 1}$ for the Discrete Gaussian Chain. More surprisingly, as opposed to the case of $2D$ Discrete Gaussian $\Psi : \mathbf{Z}^2 \to \mathbf{Z}$, we prove that the integers do not affect the {\em effective temperature} of the discrete Gaussian Chain at large scales. Such an {\em invisibility of the integers} had been predicted by Slurink and Hilhorst in the special case $\alpha_c=2$ in \cite{slurink1983roughening}. Our proof relies on four main ingredients: (1) A Caffareli-Silvestre extension for the discrete fractional Laplacian (which may be of independent interest) (2) A localisation of the chain in a smoother sub-domain (3) A Coulomb gas-type expansion in the spirit of Fr\"ohlich-Spencer \cite{FS} (4) Controlling the amount of Dirichlet Energy supported by a $1D$ band for the Green functions of $\mathbf{Z}^2$ Bessel type random walks Our results also have implications for the so-called {\em Boundary Sine-Gordon field}. Finally, we analyse the (easier) regimes where $\alpha\in(1,2) \cup (3,\infty)$ as well as the $2D$ Discrete Gaussian with long-range coupling constants (for any $\alpha>\alpha_c=4$).

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通过离散分数拉普拉奇的卡法雷利-西尔维斯特雷扩展实现离散高斯链的整数不可见性

离散高斯链是界面 $\Psi ：\mathbf{Z}\to\mathbf{Z}$ 受哈密顿方程 $$ H(\Psi)= \sum_{i\neq j}J_\alpha(|i-j|) |\Psi_i -\Psi_j|^2 $ 与长程耦合常数 $J_\alpha(k)\asymp k^{-\alpha}$ 的支配。对于[2,3]$中的任意$\alpha\并且在足够高的温度下，我们证明了这样一个$\alpha$-离散高斯链对$H(\alpha)$-分数高斯过程的不变量原理，其中赫斯特指数$H$满足$H=H(\alpha)=\frac {\alpha-2} 2$。这一结果超越了 Fr\"ohlich 和 Zegarlinski 的猜想，他们猜想离散高斯链的波动阶数为 $n^{tfrac 1 2(\alpha-2) \wedge 1}$。更令人惊奇的是，与2D$离散高斯$\Psi :\mathbf{Z}^2 \to \mathbf{Z}$的情况相反，我们证明了整数在大尺度上并不影响离散高斯链的{/emeffective temperature}。斯鲁林克和希尔霍斯特曾在《slurink1983roughening》一书中预言，在$α_c=2$的特殊情况下，整数不会影响离散高斯链的{emeffective temperature}。我们的证明依赖于四个主要成分：(1) 离散分数拉普拉奇的 Caffareli-Silvestree 扩展（这可能是独立的兴趣点） (2) 链在更平滑子域中的局部化 (3) Fr\"ohlich-Spencer \cite{FS}精神中的库仑气体型扩展(4)控制$\mathbf{Z}^2$贝塞尔型随机游走的格林函数的$1D$带所支持的狄利克特能量的数量我们的结果也对所谓的{em BoundarySine-Gordon field}有影响。最后，我们分析了$\alpha\in(1,2) \cup(3,\infty)$以及具有长程耦合常数（对于任何$\alpha>\alpha_c=4$）的2D$离散高斯（Discrete Gaussian）的（更容易）状态。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Mathematical Physics

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