Wave Turbulence on the Surface of a Fluid in a High-Gravity Environment

A. Cazaubiel; S. Mawet; A. Darras; G. Grosjean; J. J.W.A. Van Loon; S. Dorbolo; E. Falcon

doi:10.1103/PhysRevLett.123.244501

Wave Turbulence on the Surface of a Fluid in a High-Gravity Environment

A. Cazaubiel, S. Mawet, A. Darras, G. Grosjean, J. J.W.A. Van Loon, S. Dorbolo, E. Falcon^*

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article (Academic Journal) › peer-review

10 Citations (Scopus)

Abstract

We report on the observation of gravity-capillary wave turbulence on the surface of a fluid in a high-gravity environment. By using a large-diameter centrifuge, the effective gravity acceleration is tuned up to 20 times Earth's gravity. The transition frequency between the gravity and capillary regimes is thus increased up to one decade as predicted theoretically. A frequency power-law wave spectrum is observed in each regime and is found to be independent of the gravity level and of the wave steepness. While the timescale separation required by weak turbulence is well verified experimentally regardless of the gravity level, the nonlinear and dissipation timescales are found to be independent of the scale, as a result of the finite size effects of the system (large-scale container modes) that are not taken currently into account theoretically.

Original language	English
Article number	244501
Journal	Physical Review Letters
Volume	123
Issue number	24
DOIs	https://doi.org/10.1103/PhysRevLett.123.244501
Publication status	Published - 10 Dec 2019

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© 2019 American Physical Society.

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title = "Wave Turbulence on the Surface of a Fluid in a High-Gravity Environment",

abstract = "We report on the observation of gravity-capillary wave turbulence on the surface of a fluid in a high-gravity environment. By using a large-diameter centrifuge, the effective gravity acceleration is tuned up to 20 times Earth's gravity. The transition frequency between the gravity and capillary regimes is thus increased up to one decade as predicted theoretically. A frequency power-law wave spectrum is observed in each regime and is found to be independent of the gravity level and of the wave steepness. While the timescale separation required by weak turbulence is well verified experimentally regardless of the gravity level, the nonlinear and dissipation timescales are found to be independent of the scale, as a result of the finite size effects of the system (large-scale container modes) that are not taken currently into account theoretically.",

author = "A. Cazaubiel and S. Mawet and A. Darras and G. Grosjean and \{Van Loon\}, \{J. J.W.A.\} and S. Dorbolo and E. Falcon",

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doi = "10.1103/PhysRevLett.123.244501",

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T1 - Wave Turbulence on the Surface of a Fluid in a High-Gravity Environment

AU - Cazaubiel, A.

AU - Mawet, S.

AU - Darras, A.

AU - Grosjean, G.

AU - Van Loon, J. J.W.A.

AU - Dorbolo, S.

AU - Falcon, E.

PY - 2019/12/10

Y1 - 2019/12/10

N2 - We report on the observation of gravity-capillary wave turbulence on the surface of a fluid in a high-gravity environment. By using a large-diameter centrifuge, the effective gravity acceleration is tuned up to 20 times Earth's gravity. The transition frequency between the gravity and capillary regimes is thus increased up to one decade as predicted theoretically. A frequency power-law wave spectrum is observed in each regime and is found to be independent of the gravity level and of the wave steepness. While the timescale separation required by weak turbulence is well verified experimentally regardless of the gravity level, the nonlinear and dissipation timescales are found to be independent of the scale, as a result of the finite size effects of the system (large-scale container modes) that are not taken currently into account theoretically.

AB - We report on the observation of gravity-capillary wave turbulence on the surface of a fluid in a high-gravity environment. By using a large-diameter centrifuge, the effective gravity acceleration is tuned up to 20 times Earth's gravity. The transition frequency between the gravity and capillary regimes is thus increased up to one decade as predicted theoretically. A frequency power-law wave spectrum is observed in each regime and is found to be independent of the gravity level and of the wave steepness. While the timescale separation required by weak turbulence is well verified experimentally regardless of the gravity level, the nonlinear and dissipation timescales are found to be independent of the scale, as a result of the finite size effects of the system (large-scale container modes) that are not taken currently into account theoretically.

UR - https://www.scopus.com/pages/publications/85076522727

U2 - 10.1103/PhysRevLett.123.244501

DO - 10.1103/PhysRevLett.123.244501

M3 - Article (Academic Journal)

C2 - 31922874

AN - SCOPUS:85076522727

SN - 0031-9007

VL - 123

JO - Physical Review Letters

JF - Physical Review Letters

IS - 24

M1 - 244501

ER -

Wave Turbulence on the Surface of a Fluid in a High-Gravity Environment

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