Liouville Brownian motion and quantum cones in dimension $d > 2$
Abstract: For $d > 2$ and $\gamma \in (0, \sqrt{2d})$, we study the Liouville Brownian motion associated with the whole-space log-correlated Gaussian field in $\mathbb{R}d$. We compute its spectral dimension, i.e., the short-time asymptotics of the heat kernel along the diagonal, which, in contrast to the two-dimensional case, depends on both $\gamma$ and on the thickness of the starting point. Furthermore, for even dimensions $d > 2$, we show that the spherical average process of the whole-space log-correlated Gaussian field in $\mathbb{R}d$ can be identified with the integral of a stationary Gaussian Markov process of order $(d-2)/2$. Exploiting this representation, we construct the higher-dimensional analogue of the $\beta$-quantum cone for $\beta \in (-\infty, Q)$, with $Q = d/\gamma + \gamma/2$. Lastly, for $\alpha = Q - \sqrt{Q2-4}$, we prove that the law of the $d$-dimensional $\alpha$-quantum cone is invariant under shifts along the trajectories of the associated Liouville Brownian motion.
Paper Prompts
Sign up for free to create and run prompts on this paper using GPT-5.
Top Community Prompts
Collections
Sign up for free to add this paper to one or more collections.