Developed quantum turbulence and its decay

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Zeitschriftentitel:	Physics of Fluids
Personen und Körperschaften:	Skrbek, L., Sreenivasan, K. R.
In:	Physics of Fluids, 24, 2012, 1
Format:	E-Article
Sprache:	Englisch
veröffentlicht:	AIP Publishing
Schlagwörter:	Condensed Matter Physics Fluid Flow and Transfer Processes Mechanics of Materials Computational Mechanics Mechanical Engineering

author_facet	Skrbek, L. Sreenivasan, K. R. Skrbek, L. Sreenivasan, K. R.
author	Skrbek, L. Sreenivasan, K. R.
spellingShingle	Skrbek, L. Sreenivasan, K. R. Physics of Fluids Developed quantum turbulence and its decay Condensed Matter Physics Fluid Flow and Transfer Processes Mechanics of Materials Computational Mechanics Mechanical Engineering
author_sort	skrbek, l.
spelling	Skrbek, L. Sreenivasan, K. R. 1070-6631 1089-7666 AIP Publishing Condensed Matter Physics Fluid Flow and Transfer Processes Mechanics of Materials Computational Mechanics Mechanical Engineering http://dx.doi.org/10.1063/1.3678335 <jats:p>This article is primarily a review of our knowledge of the correspondence between classical and quantum turbulence, though it is interspersed with a few new interpretations. This review is deemed timely because recent work in quantum turbulence promises to provide a better understanding of aspects of classical turbulence, though the two fields of turbulence have similarities as well as differences. We pay a particular attention to the conceptually simplest case of zero temperature limit where quantum turbulence consists of a tangle of quantized vortex line and represents a simple prototype of turbulence. At finite temperature, we anchor ourselves at the level of two-fluid description of the superfluid state—consisting of a normal viscous fluid and a frictionless superfluid—and review much of the available knowledge on quantum turbulence in liquid helium (both He II and 3He-B). We consider counterflows in which the normal and superfluid components flow against each other, as well as co-flows in which the direction of the two fluids is the same. We discuss experimental methods, phenomenological results as well as key theoretical concepts.</jats:p> Developed quantum turbulence and its decay Physics of Fluids
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title	Developed quantum turbulence and its decay
title_unstemmed	Developed quantum turbulence and its decay
title_full	Developed quantum turbulence and its decay
title_fullStr	Developed quantum turbulence and its decay
title_full_unstemmed	Developed quantum turbulence and its decay
title_short	Developed quantum turbulence and its decay
title_sort	developed quantum turbulence and its decay
topic	Condensed Matter Physics Fluid Flow and Transfer Processes Mechanics of Materials Computational Mechanics Mechanical Engineering
url	http://dx.doi.org/10.1063/1.3678335
publishDate	2012
physical
description	<jats:p>This article is primarily a review of our knowledge of the correspondence between classical and quantum turbulence, though it is interspersed with a few new interpretations. This review is deemed timely because recent work in quantum turbulence promises to provide a better understanding of aspects of classical turbulence, though the two fields of turbulence have similarities as well as differences. We pay a particular attention to the conceptually simplest case of zero temperature limit where quantum turbulence consists of a tangle of quantized vortex line and represents a simple prototype of turbulence. At finite temperature, we anchor ourselves at the level of two-fluid description of the superfluid state—consisting of a normal viscous fluid and a frictionless superfluid—and review much of the available knowledge on quantum turbulence in liquid helium (both He II and 3He-B). We consider counterflows in which the normal and superfluid components flow against each other, as well as co-flows in which the direction of the two fluids is the same. We discuss experimental methods, phenomenological results as well as key theoretical concepts.</jats:p>
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author	Skrbek, L., Sreenivasan, K. R.
author_facet	Skrbek, L., Sreenivasan, K. R., Skrbek, L., Sreenivasan, K. R.
author_sort	skrbek, l.
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description	<jats:p>This article is primarily a review of our knowledge of the correspondence between classical and quantum turbulence, though it is interspersed with a few new interpretations. This review is deemed timely because recent work in quantum turbulence promises to provide a better understanding of aspects of classical turbulence, though the two fields of turbulence have similarities as well as differences. We pay a particular attention to the conceptually simplest case of zero temperature limit where quantum turbulence consists of a tangle of quantized vortex line and represents a simple prototype of turbulence. At finite temperature, we anchor ourselves at the level of two-fluid description of the superfluid state—consisting of a normal viscous fluid and a frictionless superfluid—and review much of the available knowledge on quantum turbulence in liquid helium (both He II and 3He-B). We consider counterflows in which the normal and superfluid components flow against each other, as well as co-flows in which the direction of the two fluids is the same. We discuss experimental methods, phenomenological results as well as key theoretical concepts.</jats:p>
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institution	DE-Gla1, DE-Zi4, DE-15, DE-Pl11, DE-Rs1, DE-105, DE-14, DE-Ch1, DE-L229, DE-D275, DE-Bn3, DE-Brt1, DE-D161
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spelling	Skrbek, L. Sreenivasan, K. R. 1070-6631 1089-7666 AIP Publishing Condensed Matter Physics Fluid Flow and Transfer Processes Mechanics of Materials Computational Mechanics Mechanical Engineering http://dx.doi.org/10.1063/1.3678335 <jats:p>This article is primarily a review of our knowledge of the correspondence between classical and quantum turbulence, though it is interspersed with a few new interpretations. This review is deemed timely because recent work in quantum turbulence promises to provide a better understanding of aspects of classical turbulence, though the two fields of turbulence have similarities as well as differences. We pay a particular attention to the conceptually simplest case of zero temperature limit where quantum turbulence consists of a tangle of quantized vortex line and represents a simple prototype of turbulence. At finite temperature, we anchor ourselves at the level of two-fluid description of the superfluid state—consisting of a normal viscous fluid and a frictionless superfluid—and review much of the available knowledge on quantum turbulence in liquid helium (both He II and 3He-B). We consider counterflows in which the normal and superfluid components flow against each other, as well as co-flows in which the direction of the two fluids is the same. We discuss experimental methods, phenomenological results as well as key theoretical concepts.</jats:p> Developed quantum turbulence and its decay Physics of Fluids
spellingShingle	Skrbek, L., Sreenivasan, K. R., Physics of Fluids, Developed quantum turbulence and its decay, Condensed Matter Physics, Fluid Flow and Transfer Processes, Mechanics of Materials, Computational Mechanics, Mechanical Engineering
title	Developed quantum turbulence and its decay
title_full	Developed quantum turbulence and its decay
title_fullStr	Developed quantum turbulence and its decay
title_full_unstemmed	Developed quantum turbulence and its decay
title_short	Developed quantum turbulence and its decay
title_sort	developed quantum turbulence and its decay
title_unstemmed	Developed quantum turbulence and its decay
topic	Condensed Matter Physics, Fluid Flow and Transfer Processes, Mechanics of Materials, Computational Mechanics, Mechanical Engineering
url	http://dx.doi.org/10.1063/1.3678335