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Books on the topic 'Phononic Properties'

Author: Grafiati
Published: 7 September 2023

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1

W, Eisenmenger, and Kaplyanskii A. A, eds. Nonequilibrium phonons in nonmetalliccrystals. Amsterdam: North-Holland, 1986.

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2

1930-, Eisenmenger W., and Kapli͡a︡nskiĭ A. A, eds. Nonequilibrium phonons in nonmetallic crystals. Amsterdam: North-Holland, 1986.

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3

Shank, C. V. Spectroscopy of nonequilibrium electrons and phonons. Amsterdam: North-Holland, 1992.

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4

Italian, National School on Condensed Matter (1987 Bra Italy). Physics of metals: Proceedings of the Italian National School on Condensed Matter, 21 Sep-3 Oct 1987, Bra, Italy. Singapore: World Scientific, 1988.

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5

1928-, Elliott R. J., and Ipatova I. P. 1929-, eds. Optical properties of mixed crystals. Amsterdam: North-Holland, 1988.

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6

Trallero-Giner, C. Long wave polar modes in semiconductor heterostructures. Oxford: Pergamon, 1998.

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7

Bian, Qiuping. Phonon spectra and thermal properties of some fcc metals using embedded-atom potentials. St. Catharines, Ont: Brock University, Dept. of Physics, 2005.

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8

Capelleti, Rosanna. Rare earths as a probe of environment and electron-phonon interaction in optical materials. New York: Nova Science Publishers, 2009.

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9

Alkali-doped fullerides: Narrow-based Solids with Unusual Properties. Singapore: World Scientific Pub., 2004.

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10

Ruf, Tobias. Phonon Raman-scattering in semiconductors, quantum wells and superlattices: Basic results and applications. Berlin: Springer, 1998.

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11

NATO Advanced Research Workshop on Light Scattering in Semiconductor Structures and Superlattices (1990 Mont-Tremblant, Québec). Light scattering in semiconductor structures and superlattices. New York: Plenum Press in cooperation with NATO Scientific Affairs Division, 1991.

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12

Bulk metallic glasses. Hauppauge, N.Y: Nova Science Publishers, 2011.

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13

Fekete, Gary. Phonon spectra and thermodynamic properties of rare gas solids based on empirical and semi-empirical (ab initio) two-body potentials: A comparative study. St. Catharines, Ont: Brock University, Dept. of Physics, 2007.

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14

A, Balzarotti, Guizzetti G, and Stella A, eds. Highlights on spectroscopies of semiconductors and insulators: Castro Marina, Italy, September 1987. Singapore: World Scientific, 1989.

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15

1934-, Cardona Manuel, and Merlin R. 1950-, eds. Light scattering in solids. Berlin: Springer, 2007.

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16

Adibi, Ali. Photonic and Phononic Properties of Engineered Nanostructures VI. SPIE, 2016.

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17

Adibi, Ali, Shawn-Yu Lin, and Axel Scherer. Photonic and Phononic Properties of Engineered Nanostructures III. SPIE, 2013.

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18

Scherer, Axel. Photonic and Phononic Properties of Engineered Nanostructures V. SPIE, 2015.

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19

Adibi, Ali, Shawn-Yu Lin, and Axel Scherer. Photonic and Phononic Properties of Engineered Nanostructures IV. SPIE, 2014.

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20

Adibi, Ali, Shawn-Yu Lin, and Axel Scherer. Photonic and Phononic Properties of Engineered Nanostructures VII. SPIE, 2018.

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21

Hedayatrasa, Saeid. Design Optimisation and Validation of Phononic Crystal Plates for Manipulation of Elastodynamic Guided Waves. Springer, 2018.

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22

Hedayatrasa, Saeid. Design Optimisation and Validation of Phononic Crystal Plates for Manipulation of Elastodynamic Guided Waves. Springer, 2019.

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23

Singh, M. R. Electronic, Photonic, Plasmonic, Phononic and Magnetic Properties of Nanomaterials: London, Canada, 12-16 August 2013. Unknown Publisher, 2014.

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24

Janssen, Ted, Gervais Chapuis, and Marc de Boissieu. Physical properties. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198824442.003.0005.

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Physical properties of aperiodic crystals present some theoretical challenges due to the lack of three-dimensional periodicity. For the description of the structure there is a periodic representation in higher-dimensional space. For physical properties, however, this scheme cannot be used because the mapping between interatomic forces and the high-dimensional representation is not straightforward. In this chapter methods are described to deal with these problems. First, the hydrodynamic theory of aperiodic crystals and then the phonons and phasons theory are developed and illustrated with some examples. The properties of electrons in aperiodic crystals are also presented. Finally, the experimental findings of phonon and phason modes for modulated and quasicrystals are presented. The chapter also discusses diffuse scattering, the Debye–Waller factor, and electrical conductivity.
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25

Zakharchenya, B. P., and C. V. Shank. Spectroscopy of Nonequilibrium Electrons and Phonons. Elsevier Science & Technology Books, 2012.

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26

Kurz, H., M. Cardona, W. Richter, G. Güntherodt, G. C. Cho, T. Dekorsy, N. Esser, J. Menendez, and J. B. Page. Light Scattering in Solids VIII: Fullerenes, Semiconductor Surfaces, Coherent Phonons. Springer, 2010.

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27

(Editor), George K. Horton, and A. A. Maradudin (Editor), eds. Dynamical Properties of Solids : Phonon Physics The Cutting Edge (Dynamical Properties of Solids). North Holland, 1995.

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28

Launay, Jean-Pierre, and Michel Verdaguer. The moving electron: electrical properties. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814597.003.0003.

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The three basic parameters controlling electron transfer are presented: electronic interaction, structural change and interelectronic repulsion. Then electron transfer in discrete molecular systems is considered, with cases of inter- and intramolecular transfers. The semi-classical (Marcus—Hush) and quantum models are developed, and the properties of mixed valence systems are described. Double exchange in magnetic mixed valence entities is introduced. Biological electron transfer in proteins is briefly presented. The conductivity in extended molecular solids (in particular organic conductors) is tackled starting from band theory, with examples such as KCP, polyacetylene and TTF-TCNQ. It is shown that electron–phonon interaction can change the geometrical structure and alter conductivity through Peierls distortion. Another important effect occurs in narrow-band systems where the interelectronic repulsion plays a leading role, for instance in Mott insulators.
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29

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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30

Dederichs, P. H. Point Defects in Metals II: Dynamical Properties and Diffusion Controlled Reactions. Springer, 2013.

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31

Saito, R., A. Jorio, J. Jiang, K. Sasaki, G. Dresselhaus, and M. S. Dresselhaus. Optical properties of carbon nanotubes and nanographene. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.1.

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This article examines the optical properties of single-wall carbon nanotubes (SWNTs) and nanographene. It begins with an overview of the shape of graphene and nanotubes, along wit the use of Raman spectroscopy to study the structure and exciton physics of SWNTs. It then considers the basic definition of a carbon nanotube and graphene, focusing on the crystal structure of graphene and the electronic structure of SWNTs, before describing the experimental setup for confocal resonance Raman spectroscopy. It also discusses the process of resonance Raman scattering, double-resonance Raman scattering, and the Raman signals of a SWNT as well as the dispersion behavior of second-order Raman modes, the doping effect on the Kohn anomaly of phonons, and the elastic scattering of electrons and photons. The article concludes with an analysis of excitons in SWNTs and outlines future directions for research.
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32

(Editor), C. Rizzuto, ed. Physics of Metals: Proceedings of the Italian National School on Condensed Matter. World Scientific Pub Co Inc, 1988.

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33

Trallero-Giner, C., R. Pérez-Alvarez, and F. García-Moliner. Long Wave Polar Modes in Semiconductor Heterostructures. Elsevier Science & Technology Books, 1998.

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34

Gunnarsson, Olle. Alkali-Doped Fullerides: Narrow-Band Solids with Unusual Properties. World Scientific Publishing Company, 2004.

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35

A, Khon I͡U︡, and Institut fiziki prochnosti i materialovedenii͡a︡ (Akademii͡a︡ nauk SSSR), eds. Ėlektrony i fonony v neupori͡a︡dochennykh splavakh. Novosibirsk: "Nauka," Sibirskoe otd-nie, 1989.

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36

Solymar, L., D. Walsh, and R. R. A. Syms. Dielectric materials. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198829942.003.0010.

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The macroscopic and microscopic approaches to determining polarization are explained. The types of polarization, frequency response, and anomalous dispersion are discussed. The Debye equation for orientational polarization is derived. The concept of effective field is introduced. The dispersion equations for acoustic waves and for optical phonons are derived. The properties of piezoelectricity, pyroelectricity, and ferroelectricity are discussed. The attenuation of optical fibres, the operation of a photocopier, and the ability of liquid crystals to rotate polarization are also discussed.
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37

Horing, Norman J. Morgenstern. Quantum Statistical Field Theory. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198791942.001.0001.

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The methods of coupled quantum field theory, which had great initial success in relativistic elementary particle physics and have subsequently played a major role in the extensive development of non-relativistic quantum many-particle theory and condensed matter physics, are at the core of this book. As an introduction to the subject, this presentation is intended to facilitate delivery of the material in an easily digestible form to students at a relatively early stage of their scientific development, specifically advanced undergraduates (rather than second or third year graduate students), who are mathematically strong physics majors. The mechanism to accomplish this is the early introduction of variational calculus with particle sources and the Schwinger Action Principle, accompanied by Green’s functions, and, in addition, a brief derivation of quantum mechanical ensemble theory introducing statistical thermodynamics. Important achievements of the theory in condensed matter and quantum statistical physics are reviewed in detail to help develop research capability. These include the derivation of coupled field Green’s function equations of motion for a model electron-hole-phonon system, extensive discussions of retarded, thermodynamic and non-equilibrium Green’s functions, and their associated spectral representations and approximation procedures. Phenomenology emerging in these discussions includes quantum plasma dynamic, nonlocal screening, plasmons, polaritons, linear electromagnetic response, excitons, polarons, phonons, magnetic Landau quantization, van der Waals interactions, chemisorption, etc. Considerable attention is also given to low-dimensional and nanostructured systems, including quantum wells, wires, dots and superlattices, as well as materials having exceptional conduction properties such as superconductors, superfluids and graphene.
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38

(Editor), D. J. Lockwood, and Jeff F. Young (Editor), eds. Light Scattering in Semiconductor Structures and Superlattices (NATO Science Series: B:). Springer, 1992.

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39

Ruf, Tobias. Phonon Raman Scattering in Semiconductors, Quantum Wells and Superlattices: Basic Results and Applications (Springer Tracts in Modern Physics). Springer, 1997.

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40

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

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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.
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41

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.
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42

(Editor), Angiolino Stella, ed. Highlights on Spectroscopies of Semiconductors and Insulators: Castro Marina, Italy September 1987. World Scientific Pub Co Inc, 1989.

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43

Kresin, Vladimir, Sergei Ovchinnikov, and Stuart Wolf. Superconducting State. Oxford University Press, 2021. http://dx.doi.org/10.1093/oso/9780198845331.001.0001.

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For the past almost fifty years, scientists have been trying to explain the phenomenon of superconductivity. The mechanism is the key ingredient of microscopic theory, which was developed by Bardeen, Cooper, and Schrieffer in 1957. The theory also introduced the basic concepts of pairing, coherence length, energy gap, and so on. Since then, microscopic theory has undergone an intensive development. This book provides a very detailed theoretical treatment of the key mechanisms of superconductivity, including the current state of the art (phonons, magnons, plasmons). In addition, the book contains descriptions of the properties of the key superconducting compounds that are of the most interest for science and applications. For many years, there has been a search for new materials with higher values of the main parameters, such as the critical temperature and critical current. At present, the possibility of observing superconductivity at room temperature has become perfectly realistic. That is why the book is especially concerned with high-Tc systems such as high-Tc oxides, hydrides with record values for critical temperature under high pressure, nanoclusters, and so on. A number of interesting novel superconducting systems have been discovered recently, including topological materials, interface systems, and intercalated graphene. The book contains rigorous derivations based on statistical mechanics and many-body theory. The book also provides qualitative explanations of the main concepts and results. This makes the book accessible and interesting for a broad audience.
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44

(Editor), Manuel Cardona, and Roberto Merlin (Editor), eds. Light Scattering in Solids IX (Topics in Applied Physics). Springer, 2007.

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