Discrete wave turbulence for a coupled system of quintic Schr\"odinger equations

Abstract

We derive rigorously the non-linear macroscopic system associated to a microscopic system of coupled quintic Schr\"odinger equations in the framework of discrete wave turbulence under a particular scaling law that describes the limiting process. Our system evolves from a pair of well-prepared random initial data. More precisely, in dimensions d≥2, we set up our microscopic system on a large box of size L with weak non-linearity of strength ε. In the limit L∞ and ε0, under the scaling law ε L1β=1 with β∈(1,∞), we prove that the long-time behaviour of our microscopic system is statistically described up to times δε-1 by a non-linear resonant system whose dynamics are driven by exact resonances, where δ is independent of L and ε. Our system does not display generic symmetries, in particular not mass conservation. In such systems with fewer invariances, exact resonances contribute significantly compared to quasi-resonances and are essentially responsible for the effective dynamics in the large-box limit. We justify the emergence of discrete wave turbulence for our microscopic model.

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