Search results for " Quantum turbulence"

showing 6 items of 6 documents

Refrigeration bound of heat-producing cylinders by superfluid helium

2019

In this paper we go ahead in our studies on refrigeration of nanosystems by superfluid helium, as an appealing subject for future applications to computers or astronautical precision nanodevices. We first recall the effective thermal conductivity in laminar counterflow superfluid helium through arrays of mutually parallel cylinders and we discuss the conditions for the appearance of quantum turbulence around the heat-producing cylinders. We then consider the cooling of an array of heat-producing cylindrical nanosystems by means of superfluid-helium counterflow. We discuss the upper bound on heat removal set by avoidance of quantum turbulence and avoidance of phase transition to normal He I,…

Condensed Matter::Quantum GasesPhysics::Fluid Dynamicsthermal conductivity liquid helium quantum turbulence micropores quantized vortices computer refrigeration.Mathematics; PhysicsRefrigerationExtended Thermodynamicssuperfluid heliumPhysics::Atomic and Molecular Clusterslcsh:Science (General)Settore MAT/07 - Fisica MatematicaMSC: 76A25 76F99 80A99.lcsh:Q1-390
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Effective thermal conductivity of helium II: from Landau to Gorter–Mellink regimes

2014

The size-dependent and flux-dependent effective thermal conductivity of narrow channels filled with He II is analyzed. The classical Landau evaluation of the effective thermal conductivity of quiescent He II is extended to describe the transition to fully turbulent regime, where the heat flux is proportional to the cubic root of the temperature gradient (Gorter–Mellink regime). To do so, we use an expression for the quantum vortex line density L in terms of the heat flux considering the influence of the walls. From it, and taking into account the friction force of normal component against the vortices, we compute the effective thermal conductivity as a function of the heat flux, and we disc…

PhysicsCondensed matter physicsTurbulenceApplied MathematicsGeneral MathematicsQuantum vortexGeneral Physics and Astronomychemistry.chemical_elementHeat transfer coefficientThermal conductionThermal diffusivityThermal conductivitychemistryHeat fluxThermal conductivity Liquid helium Quantum turbulence Micropores Quantized vorticesSettore MAT/07 - Fisica MatematicaHelium
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Contribution of the normal component to the thermal resistance of turbulent liquid helium

2015

Previous results for the velocity profile of the normal component of helium II in counterflow are used to evaluate the viscous contribution to the effective thermal resistance. It turns out that such a contribution becomes considerably higher than the usual Landau estimate, because in the presence of vortices, the velocity profile is appreciably different from the Poiseuille parabolic profile. Thus, a marked increase in the contribution of the normal component to the thermal resistance with respect to the viscous Landau estimate does not necessarily imply that the normal component is turbulent. Furthermore, we examine the influence of a possible slip flow along the walls when the radius of …

PhysicsCondensed matter physicsTurbulenceApplied MathematicsGeneral MathematicsThermal resistanceQuantum turbulenceGeneral Physics and AstronomyRadiusHagen–Poiseuille equationVortexPhysics::Fluid DynamicsThermal resistance – Superfluid helium – Quantum turbulence – Normal componentBoundary value problemSettore MAT/07 - Fisica MatematicaSuperfluid helium-4Zeitschrift für angewandte Mathematik und Physik
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Effective thermal conductivity of superuid helium: Laminar, turbulent and ballistic regimes

2016

Abstract In this paper we extend previous results on the effective thermal conductivity of liquid helium II in cylindrical channels to rectangular channels with high aspect ratio. The aim is to compare the results in the laminar regime, the turbulent regime and the ballistic regime, all of them obtained within a single mesoscopic formalism of heat transport, with heat flux as an independent variable.

PhysicsLiquid heliumT57-57.97Applied mathematics. Quantitative methodsCondensed matter physicsTurbulenceApplied MathematicsLiquid helium; Quantized vortices; Quantum turbulence; Thermal conductivity; Applied Mathematics;Laminar flow01 natural sciencesQuantum turbulenceIndustrial and Manufacturing Engineering010305 fluids & plasmasPhysics::Fluid DynamicsApplied MathematicThermal conductivityThermal conductivity0103 physical sciencesQuantized vortice010306 general physicsSettore MAT/07 - Fisica Matematicaquantized vorticesSuperfluid helium-4
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Transition to ballistic regime for heat transport in helium II

2014

The size-dependent and flux-dependent effective thermal conductivity of narrow capillaries filled with superfluid helium is analyzed from a thermodynamic continuum perspective. The classical Landau evaluation of the effective thermal conductivity of quiescent superfluid, or the Gorter-Mellinck regime of turbulent superfluids, are extended to describe the transition to ballistic regime in narrow channels wherein the radius $R$ is comparable to (or smaller than) the phonon mean-free path $\ell$ in superfluid helium. To do so we start from an extended equation for the heat flux incorporating non-local terms, and take into consideration a heat slip flow along the walls of the tube. This leads f…

Quantum turbulenceGeneral Physics and Astronomychemistry.chemical_elementFOS: Physical sciencesQuantum turbulencelaw.inventionSuperfluidityPhysics::Fluid DynamicsSuperconductivity (cond-mat.supr-con)Ballistic phononsThermal conductivityThermal conductivity; Liquid helium; Quantum turbulence; Micropores; Quantized vortices; Ballistic phononslawMesoscale and Nanoscale Physics (cond-mat.mes-hall)Settore MAT/07 - Fisica MatematicaHeliumLiquid heliumPhysicsMicroporesCondensed Matter - Mesoscale and Nanoscale PhysicsCondensed matter physicsLiquid heliumTurbulenceCondensed Matter - SuperconductivityMicroporeQuantized vorticeschemistryHeat fluxThermal conductivityQuantized vorticeSuperfluid helium-4
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Refrigeration of an array of cylindrical nanosystems by superfluid helium counterflow

2017

Abstract Motivated by the challenge of computer refrigeration, we study the limits set by the transition to quantum turbulence on the cooling of an array of heat-producing cylindrical nanosystems by means of superfluid-helium counterflow. The effective thermal conductivity in laminar counterflow superfluid helium is obtained in channels with rectangular cross section, through arrays of mutually parallel cylinders and in the combined situation of arrays of orthogonal cylinders inside the rectangular channel. The maximum cooling capacity is analyzed on the condition that turbulence is avoided and that the highest temperature does not exceed the lambda temperature.

Thermal conductivity Liquid helium Quantum turbulence Micropores Quantized vortices Computer refrigerationQuantum turbulenceCooling capacity01 natural sciences010305 fluids & plasmaslaw.inventionPhysics::Fluid DynamicsThermal conductivitylaw0103 physical sciencesthermal conductivity010306 general physicsSettore MAT/07 - Fisica Matematicathermal conductivity; liquid helium; quantum turbulence; micropores; quantized vortices; computer refrigerationquantized vorticesCondensed Matter::Quantum GasesFluid Flow and Transfer ProcessesPhysicsCondensed matter physicsliquid heliumTurbulenceLiquid heliumMechanical Engineeringcomputer refrigerationRefrigerationquantum turbulenceLaminar flowMechanicsCondensed Matter PhysicsmicroporesSuperfluid helium-4
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