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Main Authors: Brande, Meander Van den, Huveneers, François, Adachi, Kyosuke
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.06214
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author Brande, Meander Van den
Huveneers, François
Adachi, Kyosuke
author_facet Brande, Meander Van den
Huveneers, François
Adachi, Kyosuke
contents Nonequilibrium conditions fundamentally change how systems undergo phase separation. In systems with temperature gradients, attractive particles have been shown to form periodic patterns and steady convective currents, but a clear theoretical explanation for this behavior is still missing. Here, we present a dynamical mean-field model that describes the mechanism behind this convective phase separation. Using linear stability analysis, we show that the transition from a uniform state to a periodic pattern is driven by the emergence of a dominant unstable mode. Numerical simulations confirm the predicted phase diagram and demonstrate that these convective currents are a robust feature of the steady state, appearing regardless of the initial conditions. These results provide a direct approach for understanding how temperature gradients drive the formation of steady-state convective patterns.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06214
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Mean-Field Convective Phase Separation under Thermal Gradients
Brande, Meander Van den
Huveneers, François
Adachi, Kyosuke
Statistical Mechanics
Pattern Formation and Solitons
Nonequilibrium conditions fundamentally change how systems undergo phase separation. In systems with temperature gradients, attractive particles have been shown to form periodic patterns and steady convective currents, but a clear theoretical explanation for this behavior is still missing. Here, we present a dynamical mean-field model that describes the mechanism behind this convective phase separation. Using linear stability analysis, we show that the transition from a uniform state to a periodic pattern is driven by the emergence of a dominant unstable mode. Numerical simulations confirm the predicted phase diagram and demonstrate that these convective currents are a robust feature of the steady state, appearing regardless of the initial conditions. These results provide a direct approach for understanding how temperature gradients drive the formation of steady-state convective patterns.
title Mean-Field Convective Phase Separation under Thermal Gradients
topic Statistical Mechanics
Pattern Formation and Solitons
url https://arxiv.org/abs/2603.06214