Litcius/Paper detail

Shortcut to Geostrophy in Wave-Driven Rotating Turbulence: The Quartetic Instability

Maxime Brunet, Basile Gallet, Pierre-Philippe Cortet

2020Physical Review Letters43 citationsDOIOpen Access PDF

Abstract

We report on laboratory experiments of wave-driven rotating turbulence. A set of wave makers produces inertial-wave beams that interact nonlinearly in the central region of a water tank mounted on a rotating platform. The forcing thus injects energy into inertial waves only. For moderate forcing amplitude, part of the energy of the forced inertial waves is transferred to subharmonic waves, through a standard triadic resonance instability. This first step is broadly in line with the theory of weak turbulence. Surprisingly however, stronger forcing does not lead to an inertial-wave turbulence regime. Instead, most of the kinetic energy condenses into a vertically invariant geostrophic flow, even though the latter is unforced. We show that resonant quartets of inertial waves can trigger an instability-the "quartetic instability"-that leads to such spontaneous emergence of geostrophy. In the present experiment, this instability sets in as a secondary instability of the classical triadic instability.

Topics & Concepts

Inertial waveInstabilityPhysicsTurbulenceWave turbulenceForcing (mathematics)MechanicsAmplitudeInertial frame of referenceGeostrophic windClassical mechanicsKinetic energyMechanical waveWave propagationLongitudinal waveAtmospheric sciencesOpticsOceanographic and Atmospheric ProcessesTropical and Extratropical Cyclones ResearchOcean Waves and Remote Sensing