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Books on the topic 'Electrons dynamic'

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Published: 1 April 2023

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1

Electrode dynamics. Oxford: Oxford University Press, 1996.

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2

1939-, Plattner Helmut, ed. Electron microscopy of subcellular dynamics. Boca Raton, Fla: CRC Press, 1989.

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3

1939-, Plattner Helmut, ed. Electron microscopy of subcellular dynamics. Boca Raton, Fla: CRC Press, 1989.

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4

D, Tóth Klára Ph, and Pungor E, eds. Dynamic characteristics of ion-selective electrodes. Boca Raton, Fla: CRC Press, 1988.

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5

Designing dynamic circuit response. Raleigh, NC: SciTech Pub., 2010.

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6

H, McGuire J. Electron correlation dynamics in atomic collisions. Cambridge: Cambridge University Press, 1997.

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7

Mladenov, Valeri M., and Plamen Ch Ivanov, eds. Nonlinear Dynamics of Electronic Systems. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-08672-9.

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8

Witte, Johan F. Dynamic Offset Compensated CMOS Amplifiers. Dordrecht: Springer Netherlands, 2009.

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9

Lenz, Annika. Dynamic Decision Support for Electronic Requirements Negotiations. Wiesbaden: Springer Fachmedien Wiesbaden, 2020. http://dx.doi.org/10.1007/978-3-658-31175-9.

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10

1930-, Tsuchida E., ed. Macromolecular complexes: Dynamic interactions and electronic processes. New York, N.Y: VCH Publishers, 1991.

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11

Martin, Hollins, and Covell Alan, eds. Electromagnetism. London: Murray in association with Inner London Education Authority, 1989.

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12

Martin, Hollins, and Covell Allan, eds. Forces and fields. London: John Murray in association with Inner London Education Authority, 1989.

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13

Martin, Hollins, and Covell Allan, eds. Behaviour of matter. London: John Murray in association with Inner London Education Authority, 1989.

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14

Martin, Hollins, Covell Allan, and Advanced physicsproject for independent learning., eds. Thermal properties. London: Murray in association with Inner London Education Authority, 1989.

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15

Electron dynamics by inelastic X-ray scattering. Oxford: Oxford University Press, 2007.

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16

Günter, Mahler, May Volkhard, and Schreiber Michael 1954-, eds. Molecular electronics: Properties, dynamics, and applications. New York: Marcel Dekker, 1996.

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17

Engineers, Society of Automotive, and SAE International Congress & Exposition (1990 : Detroit, Mich.), eds. Vehicle dynamics and electronic controlled suspensions. Warrendale, PA: Society of Automotive Engineers, 1991.

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18

Wolfgang, Domcke, Yarkony David, and Köppel Horst, eds. Conical intersections: Electronic structure, dynamics & spectroscopy. River Edge, NJ: World Scientific, 2004.

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19

Soetbeer, Janne Marie. Dynamical Decoupling in Distance Measurements by Double Electron-Electron Resonance. Wiesbaden: Springer Fachmedien Wiesbaden, 2016. http://dx.doi.org/10.1007/978-3-658-14670-2.

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20

Lazutin, Leonid L. X-Ray Emission of Auroral Electrons and Magnetospheric Dynamics. Edited by Theodore J. Rosenberg. Berlin, Heidelberg: Springer Berlin Heidelberg, 1986. http://dx.doi.org/10.1007/978-3-642-70398-0.

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21

X-ray emission of auroral electrons and magnetospheric dynamics. Berlin: Springer-Verlag, 1986.

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22

Bakker, Johan Willem. Dynamic visualization of chemical processes. [Leiden: University of Leiden, 1998.

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23

Rizzi, Valerio. Real-Time Quantum Dynamics of Electron–Phonon Systems. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-96280-1.

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24

Hellman, Anders. Electron transfer and molecular dynamics at metal surfaces. Göteborg, Sweden: Dept. of Applied Physics, Chalmers University of Technology, Göteborg University, 2003.

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25

Glazov, M. M. Electron & Nuclear Spin Dynamics in Semiconductor Nanostructures. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198807308.001.0001.

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In recent years, the physics community has experienced a revival of interest in spin effects in solid state systems. On one hand, solid state systems, particularly semicon- ductors and semiconductor nanosystems, allow one to perform benchtop studies of quantum and relativistic phenomena. On the other hand, interest is supported by the prospects of realizing spin-based electronics where the electron or nuclear spins can play a role of quantum or classical information carriers. This book aims at rather detailed presentation of multifaceted physics of interacting electron and nuclear spins in semiconductors and, particularly, in semiconductor-based low-dimensional structures. The hyperfine interaction of the charge carrier and nuclear spins increases in nanosystems compared with bulk materials due to localization of electrons and holes and results in the spin exchange between these two systems. It gives rise to beautiful and complex physics occurring in the manybody and nonlinear system of electrons and nuclei in semiconductor nanosystems. As a result, an understanding of the intertwined spin systems of electrons and nuclei is crucial for in-depth studying and control of spin phenomena in semiconductors. The book addresses a number of the most prominent effects taking place in semiconductor nanosystems including hyperfine interaction, nuclear magnetic resonance, dynamical nuclear polarization, spin-Faraday and -Kerr effects, processes of electron spin decoherence and relaxation, effects of electron spin precession mode-locking and frequency focusing, as well as fluctuations of electron and nuclear spins.
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26

Glazov, M. M. Spin Systems in Semiconductor Nanostructures. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198807308.003.0002.

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This chapter is an introduction to a rich variety of effects taking place in the interacting system of electrons and nuclei in semiconductors. It includes also the basics of electronic properties of nanostructures and of spin physics, an overview of fundamental interactions in the electron and nuclear spin systems, the selection rules at optical transitions in semiconductors, spin resonance effect, as well as optical orientation, and dynamical nuclear polarization. In this chapter an analysis of particular features of spin dynamics arising in the structures with localized electrons such as quantum dots, which are studied further in the book, are addressed. The aim of this chapter is to provide basic minimum of information needed to read the remaining chapters.
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27

Stamenova, M., and S. Sanvito. Atomistic spin-dynamics. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533046.013.7.

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This article reviews recent advances towards the development of a truly atomistic time-dependent theory for spin-dynamics. The focus is on the s-d tight-binding model [where conduction electrons (s) are exchange-coupled to a number of classical spins (d)], including electrostatic corrections at the Hartree level, as the underlying electronic structure theory. In particular, the article considers one-dimensional (1D) magnetic atomic wires and their electronic structure, described by means of the s-d model. The discussion begins with an overview of the model spin Hamiltonian, followed by molecular-dynamics simulations of spin-wave dispersion in a s-d monoatomic chain and spin impurities in a non-magnetic chain. The current-induced motion in a magnetic domain wall (DW) is also explored, along with how an electric current can affect the magnetization landscape of a magnetic nano-object. The article concludes with an assessment of spin-motive force, and especially whether a driven magnetization dynamics can generate an electrical signal.
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28

Kitaoka, Yoshio, and Yoshio Kuramoto. Dynamics of Heavy Electrons. Oxford University Press, 2000.

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29

Soetbeer, Janne Marie. Dynamical Decoupling in Distance Measurements by Double Electron-Electron Resonance. Spektrum Akademischer Verlag GmbH, 2016.

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30

Soetbeer, Janne Marie. Dynamical Decoupling in Distance Measurements by Double Electron-Electron Resonance. Springer Spektrum, 2016.

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31

Glazov, M. M. Hyperfine Interaction of Electron and Nuclear Spins. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198807308.003.0004.

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This chapter discusses the key interaction–hyperfine coupling–which underlies most of phenomena in the field of electron and nuclear spin dynamics. This interaction originates from magnetic interaction between the nuclear and electron spins. For conduction band electrons in III–V or II–VI semiconductors, it is reduced to a Fermi contact interaction whose strength is proportional to the probability of finding an electron at the nucleus. A more complex situation is realized for valence band holes where hole Bloch functions vanish at the nuclei. Here the hyperfine interaction is of the dipole–dipole type. The modification of the hyperfine coupling Hamiltonian in nanosystems is also analyzed. The chapter contains also an overview of experimental data aimed at determination of the hyperfine interaction parameters in semiconductors and semiconductor nanostructures.
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32

Electron Dynamics In Molecular Interactions. Imperial College Press, 2010.

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33

Edited by Lyman Spitzer, Jr., and Jeremiah P. Ostriker. Dreams, Stars, and Electrons. Princeton University Press, 2007.

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34

Enoki, Toshiaki, Morinobu Endo, and Masatsugu Suzuki. Graphite Intercalation Compounds and Applications. Oxford University Press, 2003. http://dx.doi.org/10.1093/oso/9780195128277.001.0001.

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Graphite intercalation compounds are a new class of electronic materials that are classified as graphite-based host guest systems. They have specific structural features based on the alternating stacking of graphite and guest intercalate sheets. The electronic structures show two-dimensional metallic properties with a large variety of features including superconductivity. They are also interesting from the point of two-dimensional magnetic systems. This book presents the synthesis, crystal structures, phase transitions, lattice dynamics, electronic structures, electron transport properties, magnetic properties, surface phenomena, and applications of graphite intercalation compounds. The applications covered include batteries, highly conductive graphite fibers, exfoliated graphite and intercalated fullerenes and nanotubes.
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35

Lindner, Ernö, Klára Tóth, and Ernö Pungor. Dynamic Characteristics of Ion-Selective Electrodes. CRC Press, 2018. http://dx.doi.org/10.1201/9781351071536.

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36

Lindner, Erno. Dynamic Characteristics of Ion Selective Electrodes. Taylor & Francis Group, 2018.

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37

Lindner, Erno. Dynamic Characteristics of Ion Selective Electrodes. Taylor & Francis Group, 2018.

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38

Lindner, Erno. Dynamic Characteristics of Ion Selective Electrodes. Taylor & Francis Group, 2018.

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39

Dynamic Characteristics of Ion Selective Electrodes. Taylor & Francis Group, 2017.

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40

The Dynamic Electrode Surface (Faraday Discussions). The Royal Society of Chemistry, 2002.

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41

Lindner, Erno. Dynamic Characteristics of Ion Selective Electrodes. Taylor & Francis Group, 2018.

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42

H, McGuire J. Electron Correlation Dynamics in Atomic Collisions. Cambridge University Press, 2009.

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43

H, McGuire J. Electron Correlation Dynamics in Atomic Collisions. Cambridge University Press, 2011.

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44

(Editor), Benjamin Kazan, ed. Advances in Electronics and Electron Physics (Advances in Imaging and Electron Physics). Academic Press, 1993.

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45

Hawkes, Peter W. Advances in Electronics and Electron Physics (Advances in Imaging and Electron Physics). Academic Press, 1988.

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46

Hawkes, Peter W. Advances in Electronics and Electron Physics (Advances in Imaging and Electron Physics). Academic Press, 1990.

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47

(Editor), Benjamin Kazan, ed. Advances in Electronics and Electron Physics (Advances in Imaging and Electron Physics). Academic Press, 1991.

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48

Hawkes, Peter W. Advances in Electronics and Electron Physics (Advances in Imaging and Electron Physics). Academic Press, 1986.

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49

Advances in Electronics and Electron Physics (Advances in Imaging and Electron Physics). Academic Press, 1993.

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50

Hawkes, Peter W. Advances in Electronics and Electron Physics (Advances in Imaging and Electron Physics). Academic Press, 1986.

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