Matrix Quantization of Turbulence

TL;DR

This paper introduces a quantum matrix-based approach to model the Lorenz chaotic system, capturing classical chaos and dissipation within a non-commutative phase space framework, revealing decoherence and long-term quantum behavior.

Contribution

It provides the first explicit quantization of the Lorenz attractor using non-commutative matrices, incorporating dissipation quantum mechanically with correct classical limits.

Findings

Quantum matrices exhibit decoherence into multiple Lorenz attractors.

Volume-preserving sector maintains quantum properties in weak dissipation.

Dissipation leads to violation of quantum commutation relations.

Abstract

Based on our recent work on Quantum Nambu Mechanics $\cite{af2}$, we provide an explicit quantization of the Lorenz chaotic attractor through the introduction of Non-commutative phase space coordinates as Hermitian $ N \times N $ matrices in $ R^{3}$. For the volume preserving part, they satisfy the commutation relations induced by one of the two Nambu Hamiltonians, the second one generating a unique time evolution. Dissipation is incorporated quantum mechanically in a self-consistent way having the correct classical limit without the introduction of external degrees of freedom. Due to its volume phase space contraction it violates the quantum commutation relations. We demonstrate that the Heisenberg-Nambu evolution equations for the Matrix Lorenz system develop fast decoherence to N independent Lorenz attractors. On the other hand there is a weak dissipation regime, where the quantum mechanical properties of the volume preserving non-dissipative sector survive for long times.