Quantum-Inspired Simulation of 2D Turbulent Rayleigh-B\'enard Convection

Abstract

Turbulent thermal convection governs heat transport in systems ranging from stellar interiors to industrial heat exchangers. Two-dimensional Rayleigh-B\'enard convection serves as a paradigm for these flows, reproducing key features such as thin boundary layers, large-scale circulation, and sustained plume dynamics. While Matrix Product State (MPS) methods have demonstrated significant compression of isothermal turbulent fields, their application to buoyancy-driven flows with active thermal coupling has remained unexplored. We apply MPS to two-dimensional Rayleigh-B\'enard convection with dynamical simulations up to Ra = 1010. An a priori decomposition of DNS snapshots up to Ra = 1011 shows that the bond dimension required to represent the flow fields grows without saturation, in contrast to the plateauing of reported for velocity fields in isothermal 2D turbulence. Crucially, however, dynamical simulations solving the governing equations directly in the compressed MPS format at fixed show that the required to recover statistical observables, such as the Nusselt number, scales significantly more favorably with Ra than the a priori complexity suggests. At Ra = 1010, a relative error of 1.8\% in the mean Nusselt number is achieved with a nearly 9-fold reduction in degrees of freedom, using a comparable to that required at Ra = 109. Spectral analysis confirms the progressive recovery of spatial and temporal scales with increasing . These findings establish MPS as a scalable tool for simulating thermally driven turbulence, suggesting the method may remain viable for investigations of the ultimate regime at substantially higher Ra.