Книги: "Transport des phonons"

1

Gurevich, Vadim Lʹvovich. Transport in phonon systems. Amsterdam: North-Holland, 1986.

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2

Gurevich, V. L. Transport in phonon systems. Amsterdam: North-Holland, 1986.

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3

L̕ubomír, Hrivnák, ed. Teória tuhých látok. 2nd ed. Bratislava: Veda, vydavatel̕stvo Slovenskej akadémie vied, 1985.

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4

Ziman, J. M. Electrons and phonons: The theory of transport phenomena in solids. Oxford: Clarendon Press, 2001.

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5

Chen, Gang. Nanoscale energy transport and conversion: A parallel treatment of electrons, molecules, phonons, and photons. New York, NY: Oxford, 2004.

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6

Gang, Chen. Nanoscale energy transport and conversion: A parallel treatment of electrons, molecules, phonons, and photons. Oxford: Oxford University Press, 2005.

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7

Frey, Martin. Scattering in nanoscale devices. Konstanz: Hartung-Gorre, 2010.

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8

Li, Hai-Peng, and Rui-Qin Zhang. Phonon Thermal Transport in Silicon-Based Nanomaterials. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-2637-0.

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9

Neophytou, Neophytos. Theory and Simulation Methods for Electronic and Phononic Transport in Thermoelectric Materials. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-38681-8.

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10

Yamamoto, Takahiro, Kazuyuki Watanabe, and Satoshi Watanabe. Thermal transport of small systems. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533046.013.6.

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Анотація:

This article focuses on the phonon transport or thermal transport of small systems, including quasi-one-dimensional systems such as carbon nanotubes. The Fourier law well describes the thermal transport phenomena in normal bulk materials. However, it is no longer valid when the sample dimension reduces down to below the mean-free path of phonons. In such a small system, the phonons propagate coherently without interference with other phonons. The article first considers the Boltzmann–Peierls formula of diffusive phonon transport before discussing coherent phonon transport, with emphasis on the Landauer formulation of phonon transport, ballistic phonon transport and quantized thermal conductance, numerical calculation of the phonon-transmission function, and length dependence of the thermal conductance.

11

Aksamija, Zlatan. Nanophononics: Thermal Generation, Transport, and Conversion at the Nanoscale. Jenny Stanford Publishing, 2017.

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12

Ziman, J. M. Electrons and Phonons: Theory of Transport Phenomena in Solids. Oxford University Press, Incorporated, 1996.

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13

Aksamija, Zlatan. Nanophononics: Thermal Generation, Transport, and Conversion at the Nanoscale. Taylor & Francis Group, 2017.

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14

Aksamija, Zlatan. Nanophononics: Thermal Generation, Transport, and Conversion at the Nanoscale. Jenny Stanford Publishing, 2017.

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15

Aksamija, Zlatan. Nanophononics: Thermal Generation, Transport, and Conversion at the Nanoscale. Jenny Stanford Publishing, 2017.

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16

Aksamija, Zlatan. Nanophononics: Thermal Generation, Transport, and Conversion at the Nanoscale. Jenny Stanford Publishing, 2017.

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17

Horton, George K. Dynamical Properties of Solids: The Modern Physics of Phonons : Transport, Surfaces and Simulations (Dynamical Properties of Solids). Elsevier Science & Technology, 1990.

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18

Chen, Gang. Nanoscale Energy Transport and Conversion: A Parallel Treatment of Electrons, Molecules, Phonons, and Photons (Mit-Pappalardo Series in Mechanical Engineering). Oxford University Press, USA, 2005.

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19

Kuleyev, Igor Gaynitdinovich, Ivan Igorevich Kuleyev, Sergey Mikhailovich Bakharev, and Vladimir Vasilyevich Ustinov. Phonon Focusing and Phonon Transport: In Single-Crytal Nanostructures. de Gruyter GmbH, Walter, 2020.

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20

Kuleyev, Igor Gaynitdinovich, Ivan Igorevich Kuleyev, Sergey Mikhailovich Bakharev, and Vladimir Vasilyevich Ustinov. Phonon Focusing and Phonon Transport: In Single-Crytal Nanostructures. de Gruyter GmbH, Walter, 2020.

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21

Kuleyev, Igor Gaynitdinovich, Ivan Igorevich Kuleyev, Sergey Mikhailovich Bakharev, and Vladimir Vasilyevich Ustinov. Phonon Focusing and Phonon Transport: In Single-Crytal Nanostructures. de Gruyter GmbH, Walter, 2020.

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22

Li, Hai-Peng, and Rui-Qin Zhang. Phonon Thermal Transport in Silicon-Based Nanomaterials. Springer Singapore Pte. Limited, 2018.

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23

Tsaousidou, M. Thermopower of low-dimensional structures: The effect of electron–phonon coupling. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.13.

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Анотація:

This article examines the effect of electron-phonon coupling on the thermopower of low-dimensional structures. It begins with a review of the theoretical approaches and the basic concepts regarding phonon drag under different transport regimes in two- and one-dimensional systems. It then considers the thermopower of two-dimensional semiconductor structures, focusing on phonon drag in semi-classical two-dimensional electron gases confined in semiconductor nanostructures. It also analyzes the influence of phonon drag on the thermopower of semiconductor quantum wires and describes the phonon-drag thermopower of doped single-wall carbon nanotubes. The article compares theory and experiment in order to demonstrate the role of phonon-drag and electron-phonon coupling in the thermopower in two and one dimensions.

24

Alvarez, Pol Torres. Thermal Transport in Semiconductors: First Principles and Phonon Hydrodynamics. Springer, 2018.

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25

Alvarez, Pol Torres. Thermal Transport in Semiconductors: First Principles and Phonon Hydrodynamics. Springer International Publishing AG, 2019.

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26

Tiwari, Sandip. Semiconductor Physics. Oxford University Press, 2020. http://dx.doi.org/10.1093/oso/9780198759867.001.0001.

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Анотація:

A graduate-level text, Semiconductor physics: Principles, theory and nanoscale covers the central topics of the field, together with advanced topics related to the nanoscale and to quantum confinement, and integrates the understanding of important attributes that go beyond the conventional solid-state and statistical expositions. Topics include the behavior of electrons, phonons and photons; the energy and entropic foundations; bandstructures and their calculation; the behavior at surfaces and interfaces, including those of heterostructures and their heterojunctions; deep and shallow point perturbations; scattering and transport, including mesoscale behavior, using the evolution and dynamics of classical and quantum ensembles from a probabilistic viewpoint; energy transformations; light-matter interactions; the role of causality; the connections between the quantum and the macroscale that lead to linear responses and Onsager relationships; fluctuations and their connections to dissipation, noise and other attributes; stress and strain effects in semiconductors; properties of high permittivity dielectrics; and remote interaction processes. The final chapter discusses the special consequences of the principles to the variety of properties (consequences of selection rules, for example) under quantum-confined conditions and in monolayer semiconductor systems. The text also bring together short appendices discussing transform theorems integral to this study, the nature of random processes, oscillator strength, A and B coefficients and other topics important for understanding semiconductor behavior. The text brings the study of semiconductor physics to the same level as that of the advanced texts of solid state by focusing exclusively on the equilibrium and off-equilibrium behaviors important in semiconductors.

27

Neophytou, Neophytos. Theory and Simulation Methods for Electronic and Phononic Transport in Thermoelectric Materials. Springer, 2020.

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28

Tiwari, Sandip. Phase transitions and their devices. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198759874.003.0004.

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Phase transitions as a collective response of an ensemble, with appearance of unique stable properties spontaneously, is critical to a variety of devices: electronic, magnetic, optical, and their coupled forms. This chapter starts with a discussion of broken symmetry and its manifestation in the property changes in thermodynamic phase transition and the Landau mean-field articulation. It then follows it with an exploration of different phenomena and their use in devices. The first is ferroelectricity—spontaneous electric polarization—and its use in ferroelectric memories. Electron correlation effects are explored, and then conductivity transition from electron-electron and electron-phonon coupling and its use in novel memory and device forms. This is followed by development of an understanding of spin correlations and interactions and magnetism—spontaneous magnetic polarization. The use and manipulation of the magnetic phase transition in disk drives, magnetic and spin-torque memory as well as their stability is explored. Finally, as a fourth example, amorphous-crystalline structural transition in optical, electronic, and optoelectronic form are analyzed. This latter’s application include disk drives and resistive memories in the form of phase-change as well as those with electochemical transport.

29

S, Kevin Andrews, and Josephine M. S. Mobile Computing. Jupiter Publications Consortium, 2021. http://dx.doi.org/10.47715/jpc.b.59.2021.9788194706922.

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Rapid advancements in wireless digital networking technologies have enabled the emergence of capabilities that software systems are just now starting to utilize. Wireless computing is becoming more affordable for both enterprise customers and private customers as the expense of contact and handheld computing devices (laptop computers, hand-held phones, etc.) continues to decline. Mobile computing is not a condensed and well-studied subset of the proven and wellstudied area of distributed computing. Because of the nature of wireless communication media and the versatility of devices, radically new challenges in networking, operating systems, and information systems have been created. Additionally, many of the mobile computing applications envisaged impose novel demands on software systems. While mobile computing is still in its infancy, several fundamental principles and some seminal experimental systems have been established. Mobile Computing includes chapters that explain certain principles and frameworks, as well as software that are being implemented and evaluated at the moment. Mobile Computing is an excellent reference book and can also serve as a text for a mobile computing course. This book has been developed as per the Course syllabus of Dr. M. G. R Educational And Research Institute, Chennai, Tamil Nadu, India. This syallbus is on par with the other Universities and Deemed to be Univsersites in India. Keywords: Mobile computing, Wireless Transmission, Radio Transmission, Media Access Control, Wireless LAN, Mobile Network Layer and Transport Layer

30

S, Kevin Andrews, and Josephine M. S. Mobile Computing. Jupiter Publications Consortium, 2021. http://dx.doi.org/10.47715/jpc.b.59.2021.9788194706922.

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Анотація:

Rapid advancements in wireless digital networking technologies have enabled the emergence of capabilities that software systems are just now starting to utilize. Wireless computing is becoming more affordable for both enterprise customers and private customers as the expense of contact and handheld computing devices (laptop computers, hand-held phones, etc.) continues to decline. Mobile computing is not a condensed and well-studied subset of the proven and wellstudied area of distributed computing. Because of the nature of wireless communication media and the versatility of devices, radically new challenges in networking, operating systems, and information systems have been created. Additionally, many of the mobile computing applications envisaged impose novel demands on software systems. While mobile computing is still in its infancy, several fundamental principles and some seminal experimental systems have been established. Mobile Computing includes chapters that explain certain principles and frameworks, as well as software that are being implemented and evaluated at the moment. Mobile Computing is an excellent reference book and can also serve as a text for a mobile computing course. This book has been developed as per the Course syllabus of Dr. M. G. R Educational And Research Institute, Chennai, Tamil Nadu, India. This syallbus is on par with the other Universities and Deemed to be Univsersites in India. Keywords: Mobile computing, Wireless Transmission, Radio Transmission, Media Access Control, Wireless LAN, Mobile Network Layer and Transport Layer

Книги з теми "Transport des phonons"

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