Your search keyword '"Heat current"' showing total 1,047 results

1. Steady-state entanglement production in a quantum thermal machine with continuous feedback control.

Author

Francesco Diotallevi, Giovanni, Annby-Andersson, Björn, Samuelsson, Peter, Tavakoli, Armin, and Bakhshinezhad, Pharnam

Subjects

*QUANTUM entanglement, *BELL'S theorem, *QUANTUM teleportation, *REAL-time control, *QUBITS, *THERMAL tolerance (Physiology)

Abstract

Quantum thermal machines can generate steady-state entanglement by harvesting spontaneous interactions with local environments. However, using minimal resources and control, the entanglement is typically weak. Here, we study entanglement generation in a two-qubit quantum thermal machine in the presence of a continuous feedback protocol. Each qubit is measured continuously and the outcomes are used for real-time feedback to control the local system-environment interactions. We show that there exists an ideal operation regime where the quality of entanglement is significantly improved, to the extent that it can violate standard Bell inequalities and uphold quantum teleportation. In agreement with (Khandelwal et al 2020 New J. Phys. 22 073039), we also find, for ideal operation, that the heat current across the system is proportional to the entanglement concurrence. Finally, we investigate the robustness of entanglement production when the machine operates away from the ideal conditions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Steady-state entanglement production in a quantum thermal machine with continuous feedback control

Author

Giovanni Francesco Diotallevi, Björn Annby-Andersson, Peter Samuelsson, Armin Tavakoli, and Pharnam Bakhshinezhad

Subjects

steady state, feedback, entanglement generation, thermal machine, heat current, Science, Physics, QC1-999

Abstract

Quantum thermal machines can generate steady-state entanglement by harvesting spontaneous interactions with local environments. However, using minimal resources and control, the entanglement is typically weak. Here, we study entanglement generation in a two-qubit quantum thermal machine in the presence of a continuous feedback protocol. Each qubit is measured continuously and the outcomes are used for real-time feedback to control the local system-environment interactions. We show that there exists an ideal operation regime where the quality of entanglement is significantly improved, to the extent that it can violate standard Bell inequalities and uphold quantum teleportation. In agreement with (Khandelwal et al 2020 New J. Phys. 22 073039), we also find, for ideal operation, that the heat current across the system is proportional to the entanglement concurrence. Finally, we investigate the robustness of entanglement production when the machine operates away from the ideal conditions.

Published

2024

3. Equilibrium and Non-Equilibrium Lattice Dynamics of Anharmonic Systems.

Author

Esfarjani, Keivan and Liang, Yuan

Subjects

*THERMODYNAMICS, *LATTICE dynamics, *LATTICE theory, *FLUCTUATION-dissipation relationships (Physics), *UNIT cell, *EQUILIBRIUM, *PHONONIC crystals

Abstract

In this review, motivated by the recent interest in high-temperature materials, we review our recent progress in theories of lattice dynamics in and out of equilibrium. To investigate thermodynamic properties of anharmonic crystals, the self-consistent phonon theory was developed, mainly in the 1960s, for rare gas atoms and quantum crystals. We have extended this theory to investigate the properties of the equilibrium state of a crystal, including its unit cell shape and size, atomic positions and lattice dynamical properties. Using the equation-of-motion method combined with the fluctuation–dissipation theorem and the Donsker–Furutsu–Novikov (DFN) theorem, this approach was also extended to investigate the non-equilibrium case where there is heat flow across a junction or an interface. The formalism is a classical one and therefore valid at high temperatures. [ABSTRACT FROM AUTHOR]

Published

2022

4. Role of magnons and the size effect in heat transport through an insulating ferromagnet taking into account the magnetic field.

Author

Shklovskij, V. A. and Naboichenko, O. S.

Subjects

*MAGNONS, *MAGNETIC fields, *FERROMAGNETIC materials, *MAGNETIC properties, *HEAT transfer, *HEAT flux

Abstract

We solve a kinetic, space-dependent problem in an insulator/ferromagnet/insulator heterostructure in the presence of a magnetic field. At the same time, to interpret experiments on thermal transfer across ferromagnet / insulator boundaries, the Little acoustic mismatch theory is usually used, in which the temperature jump at the interface is determined only by the acoustic characteristics of the medium. We show that the theory of acoustic mismatch is convenient only for sufficiently thick insulating ferromagnets. Of the greatest interest to us is the opposite limiting case of thin ferrodielectric films, where the role of magnons in the formation of a temperature jump at the ferromagnet/insulator interface becomes decisive. We show that for T ≪ ΘD a nonlinear heat flux Q crossing the ferrodielectric/insulator interface, both the size effect and its decreasing dependence on the external magnetic field increase. Namely, Q depends on the magnetic properties of thin heated ferromagnetic films, and the role of magnons is essential in the heat transfer regime, which we call magnon overheating. On the contrary, for thick heated layers of a ferromagnet, Q can be described by the Little formula, which does not take into account the magnetic properties of the ferromagnet layer. [ABSTRACT FROM AUTHOR]

Published

2022

5. Temperature and Voltage

Author

Shastry, Abhay and Shastry, Abhay

Published

2019

6. Phase-dependent charge and heat current in thermally biased short Josephson junctions formed at helical edge states

Author

Paramita Dutta

Subjects

Josephson junction, heat current, helical edge states, Science, Physics, QC1-999

Abstract

We explore the phase-dependent charge and heat current in short Josephson junctions (JJs) with two normal metal regions attached at opposite ends, formed at helical edge states of two-dimensional topological insulators. For all finite phases, an asymmetry appears around the zero energy in the transmission spectra except for $\phi\! = \!n\phi_0$ , where n is a half-integer and φ _0 ( $ = 2\pi$ ) is the flux quantum. The phase-induced asymmetry plays a key role in inducing charge and heat current through the thermally biased junction. However, the current amplitudes are sensitive to the size of the junction. We show that in the short JJ when subject to a temperature gradient, the charge current shows an odd symmetry in phase. It indicates that the phase-tunable asymmetry around the zero energy is not sufficient to induce a dissipative thermoelectric current in the junction. This is in contrast to the behavior of long JJ, as shown in the literature. The phase-tunable heat currents are obtained with amplitudes set by the phase difference, base temperature, and system size.

Published

2023

7. Heat current in non-Markovian open systems

Author

Ruofan Chen

Subjects

heat current, matrix product state, time-evolving matrix product operators, path integral, Science, Physics, QC1-999

Abstract

We generalize time-evolving matrix product operators method to nonequilibrium quantum transport problems. The nonequilibrium current is obtained via numerical differentiation of the generating functional which is represented as a tensor network. The approach is numerically exact and the non-Markovian effects are fully taken into account. In the transport process, a part of the heat that flows out from a bath flows into the system and other baths, and the rest is stored in the system-bath coupling part. We take the spin-boson model as a demonstration to show the details of this heat flowing and the establishment of a steady current between two baths.

Published

2023

8. Heat current across double quantum dots in series coupled to ferromagnetic leads in antiparallel configuration within weak interdot coupling regime.

Author

Najdi, M. A., AL-Mukh, J. M., and Jassem, H. A.

Abstract

In this paper, we present the results obtained from our study on the heat current across double quantum dots in serial coupled to ferromagnetic leads (FM-DQDs-FM), when the leads magnetic moments are in antiparallel configuration. This study was done by using nonequilibrium Green's function method in the linear response regime. Our results are calculated in weak interdot coupling regime by taking all the parameters that affect the system such as intradot Coulomb correlation energy, spin–spin exchange interaction, and spin polarization on the leads. These results are accomplished as a function of temperature gradient as well as quantum dots energy levels. According to our results, it is noticed that the values of intradot Coulomb correlation energy and the spin–spin exchange interaction have significant impact on increasing the heat current that flows through our system. It is concluded that increasing or decreasing the magnitude of heat current in negative or positive thermal bias is ideal for designing high-efficiency heat diode. [ABSTRACT FROM AUTHOR]

Published

2021

9. A Primer on Thermoelectric Generators

Author

Narducci, Dario, Bermel, Peter, Lorenzi, Bruno, Wang, Ning, Yazawa, Kazuaki, Hull, Robert, Series Editor, Jagadish, Chennupati, Series Editor, Kawazoe, Yoshiyuki, Series Editor, Osgood, Richard M., Series Editor, Parisi, Jürgen, Series Editor, Pohl, Udo W., Series Editor, Seong, Tae-Yeon, Series Editor, Uchida, Shin-ichi, Series Editor, Wang, Zhiming M., Series Editor, Narducci, Dario, Bermel, Peter, Lorenzi, Bruno, Wang, Ning, and Yazawa, Kazuaki

Published

2018

10. Equilibrium and Non-Equilibrium Lattice Dynamics of Anharmonic Systems

Author

Keivan Esfarjani and Yuan Liang

Subjects

nanoscale thermal transport, anharmonicity, phonons, heat current, transmission, thermal conductance, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

In this review, motivated by the recent interest in high-temperature materials, we review our recent progress in theories of lattice dynamics in and out of equilibrium. To investigate thermodynamic properties of anharmonic crystals, the self-consistent phonon theory was developed, mainly in the 1960s, for rare gas atoms and quantum crystals. We have extended this theory to investigate the properties of the equilibrium state of a crystal, including its unit cell shape and size, atomic positions and lattice dynamical properties. Using the equation-of-motion method combined with the fluctuation–dissipation theorem and the Donsker–Furutsu–Novikov (DFN) theorem, this approach was also extended to investigate the non-equilibrium case where there is heat flow across a junction or an interface. The formalism is a classical one and therefore valid at high temperatures.

Published

2022

11. Dual Negative Differential of Heat Generation in a Strongly Correlated Quantum Dot Side-Coupled to Majorana Bound States

Author

Zhu-Hua Wang and Wen-Cheng Huang

Subjects

heat current, electron-phonon interaction, majorana fermions, quantum dot, negative differential heat generation, Physics, QC1-999

Abstract

We study theoretically the properties of local heat originated from energy exchange between electrons passing through a quantum dot (QD) coupled to a phonon bath. The dot is sandwiched between two normal metal leads and also side-coupled to Majorana bound states (MBSs) formed at opposite ends of a topological superconductor nanowire. We find that in addition to the negative differential of heat generation (NDHG) in the Coulomb blockade regime, another NDHG emerges near the leads’ Fermi level due to the dot-MBS coupling. This dual NDHG effect is robust against the variation of intradot Coulomb interaction strength, and disappears if the QD is coupled to regular Fermions. Direct hybridization between the MBSs reduces their impacts on the electronic transport processes, and eliminates the dual NDHG effect. Our results show that the dual NDHG effect is quite efficient for inferring the existence of MBSs, and may remedy some limitations of the detection schemes relying on tunneling spectroscopy technique.

Published

2021

12. Entropy-based theory of thermomagnetic phenomena.

Author

Sergeev, Andrei and Reizer, Michael

Subjects

*POYNTING theorem, *COOPER pair, *MAGNETIC materials, *FERMI energy, *MAGNETIC fields, *TOPOLOGICAL entropy

Abstract

We show that in the linear response approximation only entropy provides coupling between thermal and electric phenomena. The dissipationless quantum currents — magnetization, superconducting, persistent and topological edge currents — do not produce and transfer entropy and may be excluded from final formulas for thermomagnetic coefficients. The magnetization energy flux, c M × E , in crossed electric and magnetic fields strongly modifies the Poynting vector in magnetic materials and metamaterials, but do not contribute to the heat current. Calculating entropy fluxes of fluctuating Cooper pairs in pure and disordered superconductors, we obtained the fluctuation Nernst coefficient proportional to k B T / F ( F is the Fermi energy). We also introduce the thermomagnetic entropy per unit charge and derive the Nernst coefficient proportional to the difference of the thermoelectric and thermomagnetic entropies. This explains the Sondheimer cancellation and high sensitivity of thermomagnetic phenomena to correlations. In 2D superconductors, the transport entropy transferred by a vortex moving through the background formed by vortex–antivortex pairs is the configuration entropy of k B ⋅ ln 2 , which strongly exceeds the intrinsic entropy of vortex core. Beyond the linear response, the nonentropic forces can lead to phenomena unexpected from thermodynamics, such as vortex attraction to the moving hot spot. Quantum currents do not transfer entropy and may be used as ideal connectors to quantum nanodetectors. [ABSTRACT FROM AUTHOR]

Published

2021

13. Heat Transfer: Role of Surface Roughness

Author

Volokitin, Aleksandr I., Persson, Bo N.J., Avouris, Phaedon, Series editor, Bhushan, Bharat, Series editor, Bimberg, Dieter, Series editor, von Klitzing, Klaus, Series editor, Ning, Cun-Zheng, Series editor, Wiesendanger, Roland, Series editor, Volokitin, Aleksandr I., and Persson, Bo N.J.

Published

2017

14. Quantum coherence-control of thermal energy transport: the V model as a case study

Author

Felix Ivander, Nicholas Anto-Sztrikacs, and Dvira Segal

Subjects

coherences, thermal machine, interferences, heat current, transport, nonequilibrium steady state, Science, Physics, QC1-999

Abstract

Whether genuine quantum effects, particularly quantum coherences, can offer an advantage to quantum devices is a topic of much interest. Here, we study a minimal model, the three-level V system coupled to two heat baths, and investigate the role of quantum coherences in heat transport in both the transient regime and in the nonequilibrium steady-state. In our model, energy is exchanged between the baths through two parallel pathways, which can be made distinct through the nondegeneracy of excited levels (energy splitting Δ) and a control parameter α , which adjusts the strength of one of the arms. Using a nonsecular quantum master equation of Redfield form, we succeed in deriving closed-form expressions for the quantum coherences and the heat current in the steady state limit for closely degenerate excited levels. By including three ingredients in our analysis: nonequilibrium baths, nondegeneracy of levels, and asymmetry of pathways, we show that quantum coherences are generated and sustained in the V model in the steady-state limit if three conditions, conjoining thermal and coherent effects are simultaneously met: (i) the two baths are held at different temperatures. (ii) Bath-induced pathways do not interfere destructively. (iii) Thermal rates do not mingle with the control parameter α to destroy interference through an effective local equilibrium condition. Particularly, we find that coherences are maximized when the heat current is suppressed. Although we mainly focus on analytical results in the steady state limit, numerical simulations reveal that the transient behavior of coherences contrasts the steady-state limit: large long-lived transient coherences vanish at steady state, while weak short-lived transient coherences survive, suggesting that different mechanisms are at play in these two regimes. Enhancing either the lifetime of transient coherences or their magnitude at steady state thus requires the control and optimization of different physical parameters.

Published

2022

15. Peculiarities of development and extinguishing fires at the objects where liquified petroleum gas is stored

Author

Yu. Yu. Dendarenko, V. I. Dyven, Ye. O. Tyshchenko, and O. D. Blashchuk

Subjects

heat current, water spray, nozzle, liquefied petroleum gas, Forestry, SD1-669.5

Abstract

The possibility of using sprayed water jets is established, primarily radial air jets, in vertical and horizontal planes in order to reduce the temperature of the burning Liquefied Petroleum Gas, starting from the cut-off of its expiration into free space. Various technical means of supplying water in a spray and spray nozzles for their creation, which are used in solving the problem of reducing the temperature of the burning Liquefied Petroleum Gas are viewed. It has been established that the active phase of the sprayed water jet is most effective (0,5-0,75 of the lengths), which, acting under the cut of the flame is crushed to a finely dispersed phase under the influence of a high-speed gas jet. As can be seen from the above, the heating rate of the finely dispersed water phase is increased up to the gaseous state, which leads to a decrease of the temperature of the flame in its middle combustion zone. Consequently, in the flame temperature will be much lower than the temperature of the flame cone, and, as a result, close to the extinction temperature. The authors recommend the use of modern jet-forming devices to realize this goal – nozzles NRT-5, NRT-10, NRT-20, NRS, as well as hand nozzles of the kind RSK-50, RS-А, RS-B, PROTEK. In order to cool, for example, one horizontal ground steel tank on both sides, it is necessary to use at least two hydraulic guns, which will act as maneuvering. In this case, the flow of water from the hydraulic gun with a diameter of the nozzle 25 mm will be from 16 to 18 liters per second. Therefore, the task is to find, calculate and experimentally prove the efficiency of the thermal screen, which is created in the form of a moving water surface that can effectively protect a particular physical object from the thermal impact of the heat zone. In order to reduce the flow of water to cool the tanks, the authors suggest using the NRS to create radial (flat) water jets. Application of such a nozzle allows to increase the area of simultaneous cooling of the maximum surface area per unit time due to the expansion of the angle of the spray jet spark. The water consumption does not exceed 13 liters per second.

Published

2019

16. Thermal Effects in Spintronics: Physics and Applications

Author

Adachi, Hiroto, Maekawa, Sadamichi, Xu, Yongbing, editor, Awschalom, David D., editor, and Nitta, Junsaku, editor

Published

2016

17. From Thermal Rectifiers to Thermoelectric Devices

Author

Benenti, Giuliano, Casati, Giulio, Mejía-Monasterio, Carlos, Peyrard, Michel, Bartelmann, Matthias, Series editor, Englert, Berthold-Georg, Series editor, Hänggi, Peter, Series editor, Hjorth-Jensen, Morten, Series editor, Jones, Richard A L, Series editor, Lewenstein, Maciej, Series editor, von Löhneysen, H., Series editor, Raimond, Jean-Michel, Series editor, Rubio, Angel, Series editor, Theisen, Stefan, Series editor, Vollhardt, Prof. Dieter, Series editor, Wells, James, Series editor, Zank, Gary P., Series editor, Salmhofer, Manfred, Series editor, and Lepri, Stefano, editor

Published

2016

18. Theory of Non-Equilibrium Heat Transport in Anharmonic Multiprobe Systems at High Temperatures

Author

Keivan Esfarjani

Subjects

nanoscale thermal transport, anharmonicity, phonons, heat current, transmission, thermal conductance, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We consider the problem of heat transport by vibrational modes between Langevin thermostats connected by a central device. The latter is anharmonic and can be subject to large temperature difference and thus be out of equilibrium. We develop a classical formalism based on the equation of motion method, the fluctuation–dissipation theorem and the Novikov theorem to describe heat flow in a multi-terminal geometry. We show that it is imperative to include a quartic term in the potential energy to insure stability and to properly describe thermal expansion. The latter also contributes to leading order in the thermal resistance, while the usually adopted cubic term appears in the second order. This formalism paves the way for accurate modeling of thermal transport across interfaces in highly non-equilibrium situations beyond perturbation theory.

Published

2021

19. Heat Modulation on Target Thermal Bath via Coherent Auxiliary Bath

Author

Wen-Li Yu, Tao Li, Hai Li, Yun Zhang, Jian Zou, and Ying-Dan Wang

Subjects

heat modulation, multifunctional thermal device, coherent auxiliary bath, heat current, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We study a scheme of thermal management where a three-qubit system assisted with a coherent auxiliary bath (CAB) is employed to implement heat management on a target thermal bath (TTB). We consider the CAB/TTB being ensemble of coherent/thermal two-level atoms (TLAs), and within the framework of collision model investigate the characteristics of steady heat current (also called target heat current (THC)) between the system and the TTB. It demonstrates that with the help of the quantum coherence of ancillae the magnitude and direction of heat current can be controlled only by adjusting the coupling strength of system-CAB. Meanwhile, we also show that the influences of quantum coherence of ancillae on the heat current strongly depend on the coupling strength of system—CAB, and the THC becomes positively/negatively correlated with the coherence magnitude of ancillae when the coupling strength below/over some critical value. Besides, the system with the CAB could serve as a multifunctional device integrating the thermal functions of heat amplifier, suppressor, switcher and refrigerator, while with thermal auxiliary bath it can only work as a thermal suppressor. Our work provides a new perspective for the design of multifunctional thermal device utilizing the resource of quantum coherence from the CAB.

Published

2021

20. Effect of Inter-System Coupling on Heat Transport in a Microscopic Collision Model

Author

Feng Tian, Jian Zou, Lei Li, Hai Li, and Bin Shao

Subjects

inter-system coupling, quantum correlation, heat current, thermal rectification, collision model, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

In this paper we consider a bipartite system composed of two subsystems each coupled to its own thermal environment. Based on a collision model, we mainly study whether the approximation (i.e., the inter-system coupling is ignored when modeling the system–environment interaction) is valid or not. We also address the problem of heat transport unitedly for both excitation-conserving system–environment interactions and non-excitation-conserving system–environment interactions. For the former interaction, as the inter-system interaction strength increases, at first this approximation gets worse as expected, but then counter-intuitively gets better even for a stronger inter-system coupling. For the latter interaction with asymmetry, this approximation gets progressively worse. In this case we realize a perfect thermal rectification, and we cannot find an apparent rectification effect for the former interaction. Finally and more importantly, our results show that whether this approximation is valid or not is closely related to the quantum correlations between the subsystems, i.e., the weaker the quantum correlations, the more justified the approximation and vice versa.

Published

2021

21. Steady-state entanglement and heat current of two coupled qubits in two heat baths.

Author

Wang (王美姣), Mei-Jiao and Xia (夏云杰), Yun-Jie

Subjects

*HEAT, *BATHS, *LOW temperatures, *QUBITS

Abstract

We study the steady-state entanglement and heat current of two coupled qubits, in which one qubit is connected with either two baths with the different temperature or a bath. We construct the master equation in the eigenstate representation of two coupled qubits to describe the dynamics and derive the solutions in the steady-state with strong coupling regime between them. We have demonstrated the variations of the steady-state entanglement with respect to various parameters of the system in both equilibrium and nonequilibrium cases. We find that the coupling strengths and the energy detuning as well as the temperature gradient are beneficial to the enhancement of the entanglement in equilibrium case. In the nonequilibrium case, the temperature gradient has different effects on entanglement due to the temperature of the bath(s) which the qubits touch. We also study the heat current and their variations with the energy detuning, coupling strengths and diverse low temperature. The energy detuning has a positive (negative) effect on the heat current in the low (high) temperature; heat current also have different trends with coupling strengths increases for a given temperature. The temperature of cool bath is lower, the heat current is larger. [ABSTRACT FROM AUTHOR]

Published

2019

22. Critical heat current for operating an entanglement engine

Author

Shishir Khandelwal, Nicolas Palazzo, Nicolas Brunner, and Géraldine Haack

Subjects

quantum thermal machines, entanglement, entanglement witness, heat current, nanoscale device, Science, Physics, QC1-999

Abstract

Autonomous entanglement engines have recently been proposed to generate steady-state bipartite and multipartite entanglement exploiting only incoherent interactions with thermal baths at different temperatures. In this work, we investigate the interplay between heat current and entanglement in a two-qubit entanglement engine, deriving a critical heat current for successful operation of the engine, i.e. a cut-off above which entanglement is present. The heat current can thus be seen as a witness to the presence of entanglement. In the regime of weak-inter-qubit coupling, we also investigate the effect of two experimentally relevant parameters for the qubits, the energy detuning and tunnelling, on the entanglement production. Finally, we show that the regime of strong inter-qubit coupling provides no clear advantage over the weak regime, in the context of out-of-equilibrium entanglement engines.

Published

2020

23. Nonlinear Thermoelectric Response of Quantum Dots: Renormalized Dual Fermions Out of Equilibrium

Author

Kirchner, Stefan, Zamani, Farzaneh, Muñoz, Enrique, Zlatic, Veljko, editor, and Hewson, Alex, editor

Published

2013

24. Spin Waves, Spin Currents and Spin Seebeck Effect

Author

Adachi, Hiroto, Maekawa, Sadamichi, Ascheron, Claus, Series editor, Demokritov, Sergej O., editor, and Slavin, Andrei N., editor

Published

2013

25. Optimal flow layout and current allocation for improving the thermoelectric refrigeration system based on heat current method

Author

Jun-Hong Hao, Zexin Chen, Qun Chen, Zhihua Ge, Jian Sun, and Xiaoze Du

Subjects

Fuel Technology, Heat current, Thermoelectric cooling, Materials science, Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Thermoelectric refrigeration, Optimal flow, Energy Engineering and Power Technology, Current (fluid), Automotive engineering

Published

2021

26. The Temperature of Moving Bodies

Author

Biró, Tamás Sándor and Biró, Tamás Sándor

Published

2011

27. Phase-dependent heat current of granular Josephson junction for different geometries.

Author

Afsaneh, Elaheh and Yavari, Heshmatolah

Subjects

*JOSEPHSON junctions, *MAGNETIC fields, *SUPERCONDUCTORS, *ELECTRIC currents, *HEAT transfer

Abstract

We theoretically investigate the phase-dependent heat transport of a temperature-biased granular Josephson junction in the presence of a perpendicular magnetic field. We illustrate the influence of geometry of the junction on the thermal current. The use of granular Josephson junction rather than bulk one makes significant changes in the heat current behavior. The heat current diffraction pattern of the rectangular, circular and annular geometries with no trapped fluxons demonstrates similar to the current of s-wave superconducting junction. By increasing the number of trapped fluxon, the pattern of current behaves such as d-wave superconducting junction. The feasibility of using granular superconductors, with different geometries, controlled by the magnetic field provides an appropriate tool to obtain the desired result for a specific application. [ABSTRACT FROM AUTHOR]

Published

2018

28. Quantum Noise of Electron-Phonon Heat Current.

Author

Pekola, Jukka P. and Karimi, Bayan

Subjects

*QUANTUM noise, *ELECTRON-phonon interactions, *PHONONS, *ELECTRONS, *ENERGY dissipation

Abstract

We analyze heat current fluctuations between electrons and phonons in a metal. In equilibrium we recover the standard result consistent with the fluctuation-dissipation theorem. Here we show that heat current noise at finite frequencies remains non-vanishing down to zero temperature. From the experimental point of view, it is a small effect and up to now elusive. We briefly discuss the impact of electron-phonon heat current fluctuations on calorimetry, particularly in the regime of single microwave-photon detection. [ABSTRACT FROM AUTHOR]

Published

2018

29. The Transport Coefficients

Author

García-Colín, Leopoldo S., Dagdug, Leonardo, García-Colín, Leopoldo S., and Dagdug, Leonardo

Published

2009

30. Transport Phenomena

Author

Sólyom, Jenő and Sólyom, Jenő, editor

Published

2009

31. Free-Electron Model of Metals

Author

Sólyom, Jenő and Sólyom, Jenő, editor

Published

2009

32. Heat current across double quantum dots in series coupled to ferromagnetic leads in antiparallel configuration within weak interdot coupling regime

Author

H. A. Jassem, J. M. Al-Mukh, and M. A. Najdi

Subjects

Physics, Heat current, Condensed matter physics, Magnetic moment, Spin polarization, Exchange interaction, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Coupling (physics), Ferromagnetism, Quantum dot, Modeling and Simulation, Coulomb, Electrical and Electronic Engineering

Abstract

In this paper, we present the results obtained from our study on the heat current across double quantum dots in serial coupled to ferromagnetic leads (FM-DQDs-FM), when the leads magnetic moments are in antiparallel configuration. This study was done by using nonequilibrium Green's function method in the linear response regime. Our results are calculated in weak interdot coupling regime by taking all the parameters that affect the system such as intradot Coulomb correlation energy, spin–spin exchange interaction, and spin polarization on the leads. These results are accomplished as a function of temperature gradient as well as quantum dots energy levels. According to our results, it is noticed that the values of intradot Coulomb correlation energy and the spin–spin exchange interaction have significant impact on increasing the heat current that flows through our system. It is concluded that increasing or decreasing the magnitude of heat current in negative or positive thermal bias is ideal for designing high-efficiency heat diode.

Published

2021

33. Heat current method for integrated analysis and optimization of thermodynamic systems

Author

Xi Chen, Tian Zhao, Chen Qun, and KeLun He

Subjects

Mathematical optimization, Rankine cycle, Heat current, Computer Networks and Communications, Computer science, Stability (learning theory), Thermodynamic system, law.invention, Nonlinear system, Flow (mathematics), Control and Systems Engineering, law, Feature (machine learning), Energy (signal processing)

Abstract

Performance analysis and optimization of thermodynamic systems are important in increasing the efficiency of energy systems, but traditional approaches cannot meet the demand of high-efficiency performance analysis for complex thermodynamic systems. Based on the entransy theory, the recently developed heat current method, combined with the specialized simulation algorithm, offers a new and attractive solution for performance analysis of thermodynamic systems. This paper first presents the standardized heat current modeling strategy for thermodynamic systems, taking a Rankine cycle power generation system as an example to present the modeling procedure. Combining flow constraints and physical property constraints of working fluids, the framework of construction of a global system mathematical model is then presented. In the proposed framework, linear, nonlinear explicit, and nonlinear implicit system constraints can be separated. Consequently, the number of constraints needing to be solved iteratively is minimized. Based on this separation feature, this paper further proposes and presents a hierarchical and categorized algorithm that could reduce calculation time greatly and improve calculation stability significantly. Finally, a triple-pressure steam power generation system is investigated to demonstrate the advantages of the proposed hierarchical and categorized algorithm compared with conventional methods from the aspects of the time required for calculation and the initial values required.

Published

2021

34. Heat current rectification in a single quantum dot system with the presence and absence of the magnetic field

Author

M. K. Shamer

Subjects

Coupling, Physics, Heat current, Rectification, Condensed matter physics, Quantum dot, Coulomb, General Physics and Astronomy, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Anderson impurity model, Magnetic field, Spin-½

Abstract

In this paper, heat current through a single-level quantum dot between two non-magnetic leads has been studied. The system is in non-equilibrium caused by different temperatures at leads. The Anderson model is used to model quantum dot with a single spin-degenerated level. The equations of the energy levels and their occupation of the quantum dot are solved self-consistently; then the heat current is calculated as a function of temperature difference with the effect of the magnetic field. According to my study, four parameters must be tuned to realize heat current rectification. These parameters are: the magnetic field, the Coulomb correlation, the coupling with the leads, and the lower level with the spin $$\sigma $$ is blocked, while the upper one with spin $$\sigma $$ must be opened.

Published

2021

35. Non-Linear Thermoelectric Devices with Surface-Disordered Nanowires

Author

Peter Markoš and Khandker Muttalib

Subjects

Surface (mathematics), Technology, Materials science, Heat current, Condensed matter physics, Phonon, Geography, Planning and Development, Nanowire, 02 engineering and technology, non-linear regime, surface disorder, 021001 nanoscience & nanotechnology, 01 natural sciences, thermoelectricity, Nonlinear system, Condensed Matter::Materials Science, nanowires, 0103 physical sciences, Thermal, Thermoelectric effect, localized phonons, Current (fluid), 010306 general physics, 0210 nano-technology

Abstract

We reviewed some recent ideas to improve the efficiency and power output of thermoelectric nano-devices. We focused on two essentially independent aspects: (i) increasing the charge current by taking advantage of an interplay between the material and the thermodynamic parameters, which is only available in the non-linear regime; and (ii) decreasing the heat current by using nanowires with surface disorder, which helps excite localized phonons at random positions that can strongly scatter the propagating phonons carrying the thermal current.

Published

2021

36. Enhanced Transverse Seebeck Coefficients in 2D/2D PtSe2/MoS2 Heterostructures Using Wet-Transfer Stacking

Author

Kang, Min-Sung, Lee, Won-Yong, Yoon, Young-Gui, Choi, Jae Won, Kim, Gil-Sung, Kim, Si-Hoo, Park, No-Won, Lee, Sang-Kwon, Kang, Min-Sung, Lee, Won-Yong, Yoon, Young-Gui, Choi, Jae Won, Kim, Gil-Sung, Kim, Si-Hoo, Park, No-Won, and Lee, Sang-Kwon

Abstract

It is very challenging to estimate thermoelectric (TE) properties when applying millimeter-scale two-dimensional (2D) transition metal dichalcogenide (TMDC) materials to TE device applications, particularly their Seebeck coefficient due to their high intrinsic electrical resistance. This paper proposes an innovative approach to measure large transverse (i.e., in-plane) Seebeck coefficients for 2D TMDC materials by placing a low resistance (LR) semimetallic PtSe2 film on high-resistance (HR) semiconducting MoS2 (>10 M omega), whose internal resistance is too high to measure the Seebeck coefficient, forming a heterojunction structure using wet-transfer stacking. The vertically stacked LRPtSe2 (3 nm)/HR-MoS2 (12 nm) heterostructure film exhibits a high Seebeck coefficient > 190 mu V/K up to 5 K temperature difference. This unusual behavior can be explained by an additional Seebeck effect induced at the interface between the LR-2D/HR2D heterostructure. The proposed stacked LR-PtSe2/HR-MoS2 heterostructure film offers promising phenomena 2D/2D materials that enable innovative TE device applications.

Published

2022

37. FLOW PHASE DIAGRAM FOR THE HELIUM SUPERFLUIDS

Author

Skrbek, Ladislav, MOREAU, R., editor, and KIDA, SHIGEO, editor

Published

2006

38. Modeling and operation optimization of an integrated ground source heat pump and solar PVT system based on heat current method

Author

Jun-Hong Hao, Yingcheng Ni, Qun Chen, Maofeng Guo, Yifeng Zhang, Junjie Di, Yifeng Wang, Zhihua Ge, and Haihong Pan

Subjects

Flexibility (engineering), Work (thermodynamics), Heat current, Renewable Energy, Sustainability and the Environment, 020209 energy, Nuclear engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, law.invention, Thermal conductivity, law, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Mass flow rate, Environmental science, General Materials Science, Energy supply, 0210 nano-technology, Heat pump

Abstract

Multisource cleaning energy supply is a significant solution for reducing carbon emission and achieving carbon neutral. This paper proposed an integrated ground source heat pump-photovoltaic-thermal (GSHP-PVT) system to achieve the combined clean heating/cooling, reduce the heat transfer irreversible loss, and increase the flexibility of the system by introducing double-evaporators with different working fluids. According to the heating or cooling in day or night, we proposed five kinds of operation modes of the system in the annual year in winter, summer, and other seasons. Moreover, we applied the heat current method for constructing the overall heat current models of each operation mode. On this basis, the minimum of the total input work of the system can obtain the optimal mass flow rate allocation in each component under five operation modes. The optimization results show that the COP of the GSHP-PVT system always remains between 4 and 6 in the annual year. Meanwhile, the proposed system can effectively prevent the ground source's temperature decrease and operate with high efficiency. Besides, the increase of the total thermal conductance of this system, the PVT collector areas, and the temperature of water-antifreeze flowing out of the PVT collector can effectively improve the overall performance of the proposed system.

Published

2021

39. A Correction Factor-Based General Thermal Resistance Formula for Heat Exchanger Design and Performance Analysis

Author

Qun Chen, Tian Zhao, Xia Li, and Jun-Hong Hao

Subjects

Heat current, Materials science, 020209 energy, Thermal resistance, Flow (psychology), 02 engineering and technology, Function (mathematics), Heat transfer coefficient, Mechanics, Condensed Matter Physics, 020303 mechanical engineering & transports, Thermal conductivity, 0203 mechanical engineering, Heat transfer, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering

Abstract

Methods for the analysis of heat exchangers with various flow arrangements modeling, design, and performance are essential for heat transfer system modeling and its integration with other energy system models. This paper proposes the use of the linear-transfer law for the heat exchanger design and performance analysis as a function of the thermal resistance related to the ratio of a linear temperature difference to the total heat transfer rate. Additionally, we derived a correction factor that represents the influence of the flow arrangement on the heat transfer performance by the effective thermal conductance, as a function of correction factor, heat transfer coefficient, and surface area. Based on the effective thermal conductance, we propose the hot-end NTU and cold-end NTU for deriving a standardized and general thermal resistance formula for different types of heat exchangers by the combination of the correction factor with linear-transfer law. Moreover, for parallel-flow, cross-flow, and 1–2 Tubular Exchanger Manufacturers Association (TEMA) E shell-and-tube heat exchangers, we derived and obtained alternative correction factor expressions without introducing any temperatures. Two cases about heat exchanger design and performance analysis show that the calculation processes using the correction factor-based general thermal resistance are straightforward without any iteration and the calculation results are accurate. Finally, the experimental validation shows that the general thermal resistance formula is appropriate for analyzing the heat transfer performance. That is, the correction factor-based general thermal resistance formula provides a standardized model for heat exchanger analysis and heat transfer/integrated energy system modeling using the heat current method.

Published

2021

40. Vortex Dynamics in a Temperature Gradient

Author

Freimuth, Axel, Cardona, Manuel, editor, Fulde, Peter, editor, von Klitzing, Klaus, editor, Merlin, Roberto, editor, Queisser, Hans-Joachim, editor, Störmer, Horst, editor, Huebener, R. P., editor, Schopohl, N., editor, and Volovik, G. E., editor

Published

2002

41. Lumped Modeling of Dissipative Processes

Author

Senturia, Stephen D.

Published

2001

42. Chiral phonons in the pseudogap phase of cuprates

Author

S. Thériault, A. Ataei, J.-S. Zhou, T. Takayama, Marie-Eve Boulanger, Gael Grissonnanche, Maxime Dion, Etienne Lefrancois, Nicolas Doiron-Leyraud, Louis Taillefer, Francis Laliberte, Adrien Gourgout, H. Takagi, and S. Pyon

Subjects

Physics, Heat current, Condensed matter physics, Phonon, Mott insulator, Thermal Hall effect, General Physics and Astronomy, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 01 natural sciences, 010305 fluids & plasmas, Condensed Matter::Materials Science, Condensed Matter::Superconductivity, Phase (matter), 0103 physical sciences, Condensed Matter::Strongly Correlated Electrons, Charge carrier, Cuprate, 010306 general physics, Pseudogap

Abstract

The nature of the pseudogap phase of cuprates remains a major puzzle1,2. One of its signatures is a large negative thermal Hall conductivity3, whose origin is as yet unknown. This is observed even in the undoped Mott insulator La2CuO4, in which the charge carriers are localized and therefore cannot be responsible. Here, we show that the thermal Hall conductivity of La2CuO4 is roughly isotropic; that is, for heat transport parallel and normal to the CuO2 planes, it is nearly the same. This shows that the Hall response must come from phonons, as they are the only heat carriers that are able to move with the same ease both normal and parallel to the planes4. For doping levels higher than the critical doping level at which the pseudogap phase ends, both La1.6−xNd0.4SrxCuO4 and La1.8−xEu0.2SrxCuO4 show no thermal Hall signal for a heat current normal to the planes, which establishes that phonons have zero Hall response outside the pseudogap phase. Inside the pseudogap phase, the phonons must become chiral to generate the Hall response, but the mechanism by which this happens remains to be identified. It must be intrinsic (from a coupling of phonons to their electronic environment) rather than extrinsic (from structural defects or impurities), as these are the same on both sides of critical doping. Thermal transport measurements show that there is a thermal Hall effect in the out-of-plane direction in two cuprates in the pseudogap regime. This indicates that phonons are carrying the heat and that they have a handedness of unknown origin.

Published

2020

43. Operation Optimization of Liquid Cooling Systems in Data Centers by the Heat Current Method and Artificial Neural Network

Author

Kelun He, Wei Shao, Meng-Qi Zhang, and Qun Chen

Subjects

Heat current, Computer cooling, Computer science, 020209 energy, 02 engineering and technology, Energy consumption, Condensed Matter Physics, Energy conservation, symbols.namesake, 020303 mechanical engineering & transports, Thermal conductivity, 0203 mechanical engineering, Control theory, Lagrange multiplier, Heat exchanger, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, symbols

Abstract

Liquid cooling systems in data centers have been attracting more attentions due to its better cooling capability and less energy consumption. In order to propose an effective optimization method for the operation of indirect liquid cooling systems, this paper first constructs an experiment platform and applies the heat current method to build the global heat transfer constraints of the whole system. Particularly, the thermal conductance of each heat exchanger under different working conditions is predicted by the Artificial Neural Networks (ANN) trained by the historical data. On this basis, combining the heat transfer and fluid flow constraints together with the Lagrange multiplier method builds the optimization model with the objective of minimum pumping power consumption (PPC), solving which by the solution strategy designed obtains the optimal frequencies of the variable frequency pumps (VFPs). Operating with the optimal and other feasible operating conditions validates the optimization model. Meanwhile, the experiments with variable heat loads and flow resistances provide some guidelines for the optimal system operation. For instance, to address heat load increase of a branch, it needs to increase the frequencies of the VFPs, not only the corresponding hot loop but also the whole cold loop.

Published

2020

44. Heat vortex in hydrodynamic phonon transport of two-dimensional materials

Author

Man-Yu Shang, Zhaoli Guo, Chuang Zhang, and Jing-Tao Lü

Subjects

Physics, Multidisciplinary, Heat current, Phonon, Energy science and technology, lcsh:R, lcsh:Medicine, Classical fluids, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Hagen–Poiseuille equation, 01 natural sciences, Article, Vortex, Thermal conductivity, Nanoscience and technology, 0103 physical sciences, Second sound, lcsh:Q, 010306 general physics, 0210 nano-technology, Dispersion (water waves), lcsh:Science

Abstract

We study hydrodynamic phonon heat transport in two-dimensional (2D) materials. Starting from the Peierls-Boltzmann equation with the Callaway model approximation, we derive a 2D Guyer-Krumhansl-like equation describing hydrodynamic phonon transport, taking into account the quadratic dispersion of flexural phonons. In addition to Poiseuille flow, second sound propagation, the equation predicts heat current vortices and negative non-local thermal conductance in 2D materials, which are common in classical fluids but have not yet been considered in phonon transport. Our results also illustrate the universal transport behaviors of hydrodynamics, independent of the type of quasi-particles and their microscopic interactions.

Published

2020

45. Heat current model of solid granule cooling processes in moving packed beds and its applications

Author

Tian Zhao, Qun Chen, Xi Chen, and Wei Shao

Subjects

Cement, Packed bed, Materials science, Heat current, 020209 energy, General Chemical Engineering, Thermal resistance, Granule (cell biology), Finite difference method, 02 engineering and technology, General Chemistry, Mechanics, 021001 nanoscience & nanotechnology, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, 0210 nano-technology, Porosity

Abstract

The moving packed bed is commonly used for cooling high-temperature solid granules. Its effective and concise modelling is important for reducing the complexity of system analyses. This study defines the inlet temperature-based thermal resistance of solid granule cooling processes considering the porosity of the packed layer and constructs a heat current model of a practical moving packed bed. The corresponding governing equations are established by applying the Kirchhoff’s law in circuitous philosophy to reflect the overall heat transfer law in the entire moving packed bed with a low computational complexity. On this basis, the cooling process in a cement grate cooler is studied and the results simulated by the proposed model agree with those obtained using the finite difference method and experimental data. Meanwhile, the distribution of heat transfer rates in the cement grate cooler shows that the first stage, the following four stages, and the last four stages undertake 47.87%, 48.49%, and 3.93% of the total heat load, respectively. Moreover, the inlet temperature-based thermal resistance in the last four cooling stages accounts for 70.98% of the total thermal resistance, which can guide improvements in the cooling performance.

Published

2020

46. Phonon coupling induced thermophoresis of water confined in a carbon nanotube

Author

Sarith P. Sathian, Rakesh Rajegowda, and Abhijith Anandakrishnan

Subjects

Materials science, Heat current, Phonon, Diffusion, General Physics and Astronomy, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Thermophoresis, 0104 chemical sciences, law.invention, Coupling (electronics), Condensed Matter::Materials Science, Temperature gradient, law, Chemical physics, Heat transfer, Physics::Atomic and Molecular Clusters, Physical and Theoretical Chemistry, 0210 nano-technology

Abstract

The controlled transport of water through nanoscale devices is an important requirement in the design and development of various nanofluidic systems. Molecular dynamics simulations are performed to investigate the phonon coupling induced thermophoretic transport of water through a carbon nanotube (CNT). Phonon coupling is believed to have a significant role in the transport of heat at the liquid-solid interface. The thermally induced vibrational modes of water-filled and empty CNTs are examined at various thermal gradients. The spatial asymmetry along the length of a CNT due to the imposed thermal gradient contributes to the diffusion enhancement of water confined in the CNT, but does not have a strong correlation with the applied thermal gradient. Analysis shows that the vibrational modes present in the center-of-mass oscillations of CNTs do not play any significant role in the development of the thermophoretic force on water. The low-frequency phonon vibrational modes of CNTs are suppressed due to the phonon coupling between water and the CNT. Also, we observed that the spectral heat current across the water-CNT interface dominates at frequencies below 5 THz, which is the same frequency range as radial breathing modes observed in the vibrational spectrum of CNT. This observation leads us to the conclusion that the coupling of radial breathing phonon modes contributes significantly to thermophoresis. This study substantiates the existence of phonon coupling at the water-CNT interface and quantifies the accumulated heat transfer across the interface.

Published

2020

47. Coherence enhanced quantum metrology in a nonequilibrium optical molecule

Author

Zhihai Wang, Wei Wu, Guodong Cui, and Jin Wang

Subjects

coherence, quantum Fisher information, heat current, Science, Physics, QC1-999

Abstract

We explore the quantum metrology in an optical molecular system coupled to two environments with different temperatures, using a quantum master equation beyond secular approximation. We discover that the steady-state coherence originating from and sustained by the nonequilibrium condition can enhance quantum metrology. We also study the quantitative measures of the nonequilibrium condition in terms of the curl flux, heat current and entropy production at the steady state. They are found to grow with temperature difference. However, an apparent paradox arises considering the contrary behaviors of the steady-state coherence and the nonequilibrium measures in relation to the inter-cavity coupling strength. This paradox is resolved by decomposing the heat current into a population part and a coherence part. Only the latter, the coherence part of the heat current, is tightly connected to the steady-state coherence and behaves similarly with respect to the inter-cavity coupling strength. Interestingly, the coherence part of the heat current flows from the low-temperature reservoir to the high-temperature reservoir, opposite to the direction of the population heat current. Our work offers a viable way to enhance quantum metrology for open quantum systems through steady-state coherence sustained by the nonequilibrium condition, which can be controlled and manipulated to maximize its utility. The potential applications go beyond quantum metrology and extend to areas such as device designing, quantum computation and quantum technology in general.

Published

2018

48. Interfacial thermal transport in spin caloritronic material systems

Author

Frank Angeles, Jing Shi, Victor H. Ortiz, Qiyang Sun, Chen Li, and Richard Wilson

Subjects

Materials science, Heat current, Physics and Astronomy (miscellaneous), Condensed matter physics, Non-blocking I/O, Yttrium iron garnet, chemistry.chemical_element, Conductance, Material system, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, chemistry.chemical_compound, Thulium, chemistry, 0103 physical sciences, Sapphire, General Materials Science, 010306 general physics, 0210 nano-technology, Spin-½

Abstract

Interfaces often govern the thermal performance of nanoscale devices and nanostructured materials. As a result, accurate knowledge of thermal interface conductance is necessary to model the temperature response of nanoscale devices or nanostructured materials to heating. Here, we report the thermal boundary conductance between metals and insulators that are commonly used in spin-caloritronic experiments. We use time-domain thermoreflectance to measure the interface conductance between metals such as Au, Pt, Ta, Cu, and Al with garnet and oxide substrates, e.g., NiO, yttrium iron garnet (YIG), thulium iron garnet (TmIG), ${\mathrm{Cr}}_{2}{\mathrm{O}}_{3}$, and sapphire. We find that, at room temperature, the interface conductance in these types of material systems range from 50 to $300\phantom{\rule{0.16em}{0ex}}\mathrm{MW}\phantom{\rule{0.16em}{0ex}}{\mathrm{m}}^{\ensuremath{-}2}\phantom{\rule{0.16em}{0ex}}{\mathrm{K}}^{\ensuremath{-}1}$. We also measure the interface conductance between Pt and YIG at temperatures between 80 and 350 K. At room temperature, the interface conductance of Pt/YIG is $170\phantom{\rule{0.16em}{0ex}}\mathrm{MW}\phantom{\rule{0.16em}{0ex}}{\mathrm{m}}^{\ensuremath{-}2}\phantom{\rule{0.16em}{0ex}}{\mathrm{K}}^{\ensuremath{-}1}$ and the Kapitza length is \ensuremath{\sim}40 nm. A Kapitza length of 40 nm means that, in the presence of a steady-state heat current, the temperature drop at the Pt/YIG interface is equal to the temperature drop across a 40-nm-thick layer of YIG. At 80 K, the interface conductance of Pt/YIG is $60\phantom{\rule{0.16em}{0ex}}\mathrm{MW}\phantom{\rule{0.16em}{0ex}}{\mathrm{m}}^{\ensuremath{-}2}\phantom{\rule{0.16em}{0ex}}{\mathrm{K}}^{\ensuremath{-}1}$, corresponding to a Kapitza length of \ensuremath{\sim}300 nm.

Published

2021

49. Anomalous Thermal Conductivity in Very Dilute 3He-4He Solutions

Author

Ferrell, Richard A., Wyatt, A. F. G., editor, and Lauter, H. J., editor

Published

1991

50. Transport Properties of Very Dilute Superfluid Mixtures of 3He in 4He

Author

Meyer, H., Tuttle, J., Zhong, F., Wyatt, A. F. G., editor, and Lauter, H. J., editor

Published

1991