Research

Hydrodynamics, fluctuations, and exact results in non-equilibrium systems.

My work sits at the interface of statistical physics, probability, and mathematical physics. I am interested in emergent hydrodynamics, large deviations, stochastic processes, and random matrix theory, with an emphasis on exact results and asymptotic analysis.

Themes

Main directions

Emergent hydrodynamics

I study how effective hydrodynamic descriptions arise in interacting particle systems and many-body models with non-trivial transport structure.

Large deviations and current fluctuations

A central direction of my work concerns rare-event theory, fluctuation statistics, and exact results for currents and related observables.

Stochastic processes and matrix methods

I am also interested in probabilistic models and spectral structures that connect stochastic dynamics, transport, and random matrix phenomena.

Selected work

Selected publications

2025

Analytical calculations Asymptotics Numerics HPC Julia Python

Profiles

For a complete and up-to-date publication list, the best entry points are my Google Scholar and arXiv profiles.

Google Scholar arXiv

Hydrodynamics, fluctuations, and exact results in non-equilibrium systems.

Main directions

Emergent hydrodynamics

Large deviations and current fluctuations

Stochastic processes and matrix methods

Selected publications

Universal Random Matrix Behavior of a Fermionic Quantum Gas

Proxitaxis: An Adaptive Search Strategy Based on Proximity and Stochastic Resetting

Quantum Fluctuating Theory for One-Dimensional Shock Waves

Generalized Arcsine Laws for a Sluggish Random Walker with Subdiffusive Growth

Exact Large-Scale Fluctuations of the Phase Field in the Sine-Gordon Model

The Hydrodynamic Theory of Dynamical Correlation Functions in the XX Chain