Topological Pathways to Two-Dimensional Quantum Turbulence

R. Panico; G. Ciliberto; G. I. Martone; Thibault Congy; D. Ballarini; A. S. Lanotte; Nicolas Pavloff

doi:10.48550/arXiv.2411.11671

Topological Pathways to Two-Dimensional Quantum Turbulence

R. Panico, G. Ciliberto, G. I. Martone, Thibault Congy, D. Ballarini, A. S. Lanotte, Nicolas Pavloff

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Abstract

We present a combined experimental and theoretical investigation of the formation and decay kinetics of vortices in two dimensional, compressible quantum turbulence. We follow the temporal evolution of a quantum fluid of exciton polaritons, hybrid light matter quasiparticles, and measure both phase and modulus of the order parameter in the turbulent regime. Fundamental topological conservation laws require that the formation and annihilation of vortices also involve critical points of the velocity field, namely nodes and saddles. Identifying the simplest mechanisms underlying these processes enables us to develop an effective kinetic model that closely aligns with the experimental observations, and shows that different processes are responsible for vortex number growth and decay. These findings underscore the crucial role played by topological constraints in shaping nonlinear, turbulent evolution of two dimensional quantum fluids.

Original language	English
Place of Publication	Ithaca, US
Publisher	Cornell University
Pages	1-8
Number of pages	8
DOIs	https://doi.org/10.48550/arXiv.2411.11671
Publication status	Submitted - 18 Nov 2024

Keywords

cond-mat.quant-gas
physics.flu-dyn
physics.optics

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10.48550/arXiv.2411.11671Licence: CC BY

2411.11671v1Submitted manuscript, 2.58 MBLicence: CC BY

1 Letter

Topological pathways to two-dimensional quantum turbulence
Panico, R., Ciliberto, G., Martone, G. I., Congy, T., Ballarini, D., Lanotte, A. S. & Pavloff, N., 11 Jun 2025, In: Physical Review Research. 7, 2, 7 p., L022063.
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abstract = "We present a combined experimental and theoretical investigation of the formation and decay kinetics of vortices in two dimensional, compressible quantum turbulence. We follow the temporal evolution of a quantum fluid of exciton polaritons, hybrid light matter quasiparticles, and measure both phase and modulus of the order parameter in the turbulent regime. Fundamental topological conservation laws require that the formation and annihilation of vortices also involve critical points of the velocity field, namely nodes and saddles. Identifying the simplest mechanisms underlying these processes enables us to develop an effective kinetic model that closely aligns with the experimental observations, and shows that different processes are responsible for vortex number growth and decay. These findings underscore the crucial role played by topological constraints in shaping nonlinear, turbulent evolution of two dimensional quantum fluids. ",

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AU - Lanotte, A. S.

AU - Pavloff, Nicolas

PY - 2024/11/18

Y1 - 2024/11/18

N2 - We present a combined experimental and theoretical investigation of the formation and decay kinetics of vortices in two dimensional, compressible quantum turbulence. We follow the temporal evolution of a quantum fluid of exciton polaritons, hybrid light matter quasiparticles, and measure both phase and modulus of the order parameter in the turbulent regime. Fundamental topological conservation laws require that the formation and annihilation of vortices also involve critical points of the velocity field, namely nodes and saddles. Identifying the simplest mechanisms underlying these processes enables us to develop an effective kinetic model that closely aligns with the experimental observations, and shows that different processes are responsible for vortex number growth and decay. These findings underscore the crucial role played by topological constraints in shaping nonlinear, turbulent evolution of two dimensional quantum fluids.

AB - We present a combined experimental and theoretical investigation of the formation and decay kinetics of vortices in two dimensional, compressible quantum turbulence. We follow the temporal evolution of a quantum fluid of exciton polaritons, hybrid light matter quasiparticles, and measure both phase and modulus of the order parameter in the turbulent regime. Fundamental topological conservation laws require that the formation and annihilation of vortices also involve critical points of the velocity field, namely nodes and saddles. Identifying the simplest mechanisms underlying these processes enables us to develop an effective kinetic model that closely aligns with the experimental observations, and shows that different processes are responsible for vortex number growth and decay. These findings underscore the crucial role played by topological constraints in shaping nonlinear, turbulent evolution of two dimensional quantum fluids.

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KW - physics.optics

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BT - Topological Pathways to Two-Dimensional Quantum Turbulence

PB - Cornell University

CY - Ithaca, US

ER -

Topological Pathways to Two-Dimensional Quantum Turbulence

Abstract

Keywords

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Research output

Topological pathways to two-dimensional quantum turbulence

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