Home > Research > Publications & Outputs > Capillary turbulence on the surfaces of quantum...

Research

Associated organisational unit

View graph of relations

Capillary turbulence on the surfaces of quantum fluids.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNChapter

Published

Standard

Capillary turbulence on the surfaces of quantum fluids. / Kolmakov, G. V.; Brazhnikov, M. Y.; Levchenko, A. A. et al.
Quantum Turbulence. ed. / M. Tsubota; W. P. Halperin. 16. ed. Amsterdam: Elsevier, 2009. p. 305-349 (Progress in Low Temperature Physics).

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNChapter

Harvard

Kolmakov, GV, Brazhnikov, MY, Levchenko, AA, Abdurakhimov, LV, McClintock, PVE & Mezhov-Deglin, LP 2009, Capillary turbulence on the surfaces of quantum fluids. in M Tsubota & WP Halperin (eds), Quantum Turbulence. 16 edn, Progress in Low Temperature Physics, Elsevier, Amsterdam, pp. 305-349.

APA

Kolmakov, G. V., Brazhnikov, M. Y., Levchenko, A. A., Abdurakhimov, L. V., McClintock, P. V. E., & Mezhov-Deglin, L. P. (2009). Capillary turbulence on the surfaces of quantum fluids. In M. Tsubota, & W. P. Halperin (Eds.), Quantum Turbulence (16 ed., pp. 305-349). (Progress in Low Temperature Physics). Elsevier.

Vancouver

Kolmakov GV, Brazhnikov MY, Levchenko AA, Abdurakhimov LV, McClintock PVE, Mezhov-Deglin LP. Capillary turbulence on the surfaces of quantum fluids. In Tsubota M, Halperin WP, editors, Quantum Turbulence. 16 ed. Amsterdam: Elsevier. 2009. p. 305-349. (Progress in Low Temperature Physics).

Author

Kolmakov, G. V. ; Brazhnikov, M. Y. ; Levchenko, A. A. et al. / Capillary turbulence on the surfaces of quantum fluids. Quantum Turbulence. editor / M. Tsubota ; W. P. Halperin. 16. ed. Amsterdam : Elsevier, 2009. pp. 305-349 (Progress in Low Temperature Physics).

Bibtex

@inbook{3e1e73c2de774aa88796062101badd20,
title = "Capillary turbulence on the surfaces of quantum fluids.",
abstract = "We discuss the results of recent studies of weak turbulence in asystem of capillary waves on the surface of liquid hydrogen and of helium 4He in normal and superfluid state. It was observed that when the driving amplitude was sufficiently high, a steady state direct Kolmogorov-Zakharov cascade is formed involving a flux of energy towards high frequencies. The wave amplitude distribution follows a power-law over a wide range of frequencies, in agreement with the weak turbulence theory. It was found that the decay of capillary turbulence begins from the high-frequency end of the spectral range, while most of the energy remains localised at low frequencies. We show that this process can be accounted for in terms of a quasiadiabatic decay wherein fast nonlinear wave interactions redistribute energy between frequency scales in the presence of finite damping at all frequencies. Our numericalmcalculations based on this idea agree well with experimental data.",
author = "Kolmakov, {G. V.} and Brazhnikov, {M. Y.} and Levchenko, {A. A.} and Abdurakhimov, {L. V.} and McClintock, {P. V. E.} and Mezhov-Deglin, {L. P.}",
year = "2009",
language = "English",
isbn = "9780080548104 0080548105",
series = "Progress in Low Temperature Physics",
publisher = "Elsevier",
pages = "305--349",
editor = "M. Tsubota and Halperin, {W. P.}",
booktitle = "Quantum Turbulence",
edition = "16",

}

RIS

TY - CHAP

T1 - Capillary turbulence on the surfaces of quantum fluids.

AU - Kolmakov, G. V.

AU - Brazhnikov, M. Y.

AU - Levchenko, A. A.

AU - Abdurakhimov, L. V.

AU - McClintock, P. V. E.

AU - Mezhov-Deglin, L. P.

PY - 2009

Y1 - 2009

N2 - We discuss the results of recent studies of weak turbulence in asystem of capillary waves on the surface of liquid hydrogen and of helium 4He in normal and superfluid state. It was observed that when the driving amplitude was sufficiently high, a steady state direct Kolmogorov-Zakharov cascade is formed involving a flux of energy towards high frequencies. The wave amplitude distribution follows a power-law over a wide range of frequencies, in agreement with the weak turbulence theory. It was found that the decay of capillary turbulence begins from the high-frequency end of the spectral range, while most of the energy remains localised at low frequencies. We show that this process can be accounted for in terms of a quasiadiabatic decay wherein fast nonlinear wave interactions redistribute energy between frequency scales in the presence of finite damping at all frequencies. Our numericalmcalculations based on this idea agree well with experimental data.

AB - We discuss the results of recent studies of weak turbulence in asystem of capillary waves on the surface of liquid hydrogen and of helium 4He in normal and superfluid state. It was observed that when the driving amplitude was sufficiently high, a steady state direct Kolmogorov-Zakharov cascade is formed involving a flux of energy towards high frequencies. The wave amplitude distribution follows a power-law over a wide range of frequencies, in agreement with the weak turbulence theory. It was found that the decay of capillary turbulence begins from the high-frequency end of the spectral range, while most of the energy remains localised at low frequencies. We show that this process can be accounted for in terms of a quasiadiabatic decay wherein fast nonlinear wave interactions redistribute energy between frequency scales in the presence of finite damping at all frequencies. Our numericalmcalculations based on this idea agree well with experimental data.

M3 - Chapter

SN - 9780080548104 0080548105

T3 - Progress in Low Temperature Physics

SP - 305

EP - 349

BT - Quantum Turbulence

A2 - Tsubota, M.

A2 - Halperin, W. P.

PB - Elsevier

CY - Amsterdam

ER -