Decay of correlations for the massless hierarchical Liouville model in infinite volume (2408.16649v1)
Abstract: Let $(A_v){v\in \mathcal{T}}$ be the balanced Gaussian Branching Random Walk on a $d$-ary tree $\mathcal{T}$ and let $MA$ be the multiplicative chaos with parameter $\gamma \in (0, \sqrt{2\log d})$ constructed from $A$. In this work we establish the precise first order asymptotics of negative exponential moment of $MA$, i.e.\ we prove that for $t_k = \lambda p\gammak$ with $\lambda>0$ and $p_\gamma$ an explicit constant depending only on $\gamma$, we have as $k \to \infty$, \begin{equation} -\frac{1}{dk} \log \mathbb{E}[e{-\lambda p_\gammak MA } ] \to h(\lambda), \end{equation} where $h\colon (0,\infty)\to \mathbb{R}$ is a non-explicit positive continuous function. This result allows us to study the law of $A$ tilted by $e{-t_k MA}$ for particular values of $\lambda$, with $k\to \infty$. In this setting we prove that the normalized $L1$ norm of $A$ in generation $k-a$ is bounded and converges to $0$ when first $k\to \infty$ and then $a\to 0$. As an application we prove that in this setting, under the tilt $e{-t_k MA}$ and with $k\to \infty$, the Branching Random Walk $A$ exhibits a weak decay of correlation, which is not present in the non-tilted model. Our methods also apply to the usual Branching Random Walk $(S_v){v\in \mathcal{T}}$ and with $MA$ replaced by $\frac{1}{2}(M+ + M- )$, where $M+$ and $M-$ are the multiplicative chaoses with parameter $\gamma \in (0, \sqrt{2\log d})$ constructed from $S$ and $-S$. In that case we prove that, as $k\to \infty$, \begin{equation} -\frac{1}{dk} \log \mathbb{E}[e{- \frac{\lambda p\gammak}{2}( M+ + M-) }] \to \tilde h(\lambda), \end{equation} where $\tilde h\colon (0,\infty)\to \mathbb{R}$ is again a non-explicit positive continuous function.