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Books on the topic 'THz Spintronic'

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Published: 25 May 2024

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1

(Hideaki), Takayanagi H., Nitta Junsaku, and Nakano Hayato, eds. Controllable quantum states: Mesoscopic Superconductivity and Spintronics : proceedings of the International Symposium. New Jersey: World Scientific Publishing Co., 2008.

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2

H, Takayanagi, and Nitta Junsaku, eds. Towards the controllable quantum states: Mesoscopic superconductivity and spintronics : Atsugi, Kanagawa, Japan, 4-6 March 2002. River Edge, N.J: World Scientific, 2003.

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3

International Symposium on Mesoscopic Superconductivity and Spintronics (2004 Atsugi, Kanagawa, Japan). Realizing controllable quantum states: Mesoscopic superconductivity and spintronics ın the light of quantum computation : Atsugi, Kanagawa, Japan, 1-4 March 2004. Edited by Takayanagi H and Nitta Junsaku. Singapore: World Scientific, 2005.

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4

The elements of continuum mechanics. 2nd ed. New York: Springer-Verlag, 1985.

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5

IFF-Ferienkurs (34th 2003 Forschungszentrum Jülich). Fundamentals of nanoelectronics: Lecture manuscripts of the 34th Spring School of the Department of Solid State Research : this spring school was organized on March 10-21, 2003 in the Forschungszentrum Jülich GmbH by the Institut für Festkörperforschung in collaboration with universities, research institutes and the industry. Jülich: Forschungszentrum Jülich, Institut für Festkörperforschung, 2003.

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6

International Winter School on New Developments in Solid State Physics (13th 2004 Mauterndorf, Austria). Proceedings of the Thirteenth International Winterschool on New Developments in Solid State Physics: Low-dimensional systems : held in Mauterndorf, Austria, 15-20 February 2004. Edited by Bauer G. 1942-, Jantsch W. 1946-, and Kuchar F. 1941-. Amsterdam, The Netherlands: Elsevier, 2004.

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7

International Winter School on New Developments in Solid State Physics (13th 2004 Mauterndorf, Austria). Proceedings of the Thirteenth International Winterschool on New Developments in Solid State Physics: Low-dimensional systems : held in Mauterndorf, Austria, 15-20 February 2004. Edited by Bauer G. 1942-, Jantsch W. 1946-, and Kuchar F. 1941-. Amsterdam, The Netherlands: Elsevier, 2004.

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8

Dieter, Dahmen Hans, and SpringerLink (Online service), eds. The Picture Book of Quantum Mechanics. 4th ed. New York, NY: Springer New York, 2012.

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9

service), SpringerLink (Online, ed. Atomic Scale Interconnection Machines: Proceedings of the 1st AtMol European Workshop Singapore 28th-29th June 2011. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012.

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10

Lorente, Nicolas. Architecture and Design of Molecule Logic Gates and Atom Circuits: Proceedings of the 2nd AtMol European Workshop. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013.

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11

T, Stroh, Dahmen H. D, and SpringerLink (Online service), eds. Interactive Quantum Mechanics: Quantum Experiments on the Computer. New York, NY: Springer Science+Business Media, LLC, 2011.

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12

Ansermet, J. Ph. Spintronics with metallic nanowires. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.3.

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This article focuses on spintronics with metallic nanowires. It begins with a review of the highlights of spintronics research, paying attention to the very important developments accomplished with tunnel junctions. It then considers the effect of current on magnetization before discussing spin diffusion and especially spin-dependent conductivities, spin-diffusion lengths, and spin accumulation. It also examines models for spin-polarized currents acting on magnetization, current-induced magnetization switching, and current-driven magnetic excitations. It concludes with an overview of resonant-current excitations, with emphasis on spin-valves and tunnel junctions as well as resonant excitation of spin-waves, domain walls and vortices. In addition, the article reflects on the future of spintronics, citing in particular the potential of the spin Hall effect as the method of generating spin accumulation, free of charge accumulation.
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13

Blamire, M. G., and J. W. A. Robinson. Superconducting Spintronics and Devices. Edited by A. V. Narlikar. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780198738169.013.14.

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This article reviews the current status of superconducting spintronics and devices, with particular emphasis on the critical issues and developments needed for their application to low-power quantum computing. It first provides an overview of conventional spintronics before discussing the rationale for superconducting spintronics. It then considers the proximity effects and Josephson junctions in superconductor-ferromagnet heterostructures, along with spin transport in the superconducting state. It also examines the issue of memory in superconducting spintronics, especially with respect to reading and writing magnetic data via superconducting states, and how to generate memory logic in such devices. Finally, it evaluates the potential application of superconductor-ferromagnetic insulator devices as thermoelectric systems in low-temperature electronic circuits.
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14

Melnikov, D. V., J. Kim, L. X. Zhang, and J. P. Leburton. Few-electron quantum-dot spintronics. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.2.

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This article examines the spin and charge properties of double and triple quantum dots (QDs) populated containing just a few electrons, with particular emphasis on laterally coupled QDs. It first describes the theoretical approach, known as exact diagonalization method, utilized on the example of the two-electron system in coupled QDs that are modelled as two parabolas. The many-body problem is solved via the exact diagonalization method as well as variational Heitler–London and Monte Carlo methods. The article proceeds by considering the general characteristics of the two-electron double-QD structure and limitations of the approximate methods commonly used for its theoretical description. It also discusses the stability diagram for two circular dots and investigates how its features are affected by the QD elliptical deformations. Finally, it assesses the behavior of the two-electron system in the realistic double-dot confinement potentials.
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15

Launay, Jean-Pierre, and Michel Verdaguer. The mastered electron: molecular electronics and spintronics, molecular machines. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814597.003.0005.

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After a historical account of the evolution which led to the concept of Molecular Electronics, the “Hybrid Molecular Electronics” approach (that is, molecules connected to nanosized metallic electrodes) is discussed. The different types of transport (one-step, two-step with different forms of tunnelling) are described, including the case where the molecule is paramagnetic (Kondo resonance). Several molecular achievements are presented: wires, diodes, memory cells, field-effect transistors, switches, using molecules, but also carbon nanotubes. A spin-off result is the possibility of imaging Molecular Orbitals. The emerging field of molecular spintronics is presented. Besides hybrid devices, examples are given of electronic functionalities using ensembles of molecules, either in solution (logical functions) or in the solid state (memory elements). The relation with the domain of Quantum Computing is presented, including the particular domain of Quantum Hamiltonian Computing. The chapter finishes by an introduction to molecular machines, with the problem of the directional control of their motion.
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16

Toward the Controllable Quantum States: Mesoscopic Superconductivity and Spintronics. World Scientific Pub Co Inc, 2003.

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17

Wernsdorfer, W. Molecular nanomagnets. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.4.

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This article describes the quantum phenomena observed in molecular nanomagnets. Molecular nanomagnets, or single-molecule magnets (SMMs), provides a fundamental link between spintronics and molecular electronics. SMMs combine the classic macroscale properties of a magnet with the quantum properties of a nanoscale entity. The resulting field, molecular spintronics, aims at manipulating spins and charges in electronic devices containing one or more molecules. This article first considers molecular nanomagnets and the giant spin model for nanomagnets before discussing the quantum dynamics of a dimer of nanomagnets, resonant photon absorption in Cr7Ni antiferromagnetic rings, and photon-assisted tunnelling in a single-molecule magnet. It also examines environmental decoherence effects in nanomagnets and concludes by highlighting the new trends towards molecular spintronics using junctions and nano-SQUIDs.
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18

Narlikar, A. V., and Y. Y. Fu, eds. Oxford Handbook of Nanoscience and Technology. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.001.0001.

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This volume highlights engineering and related developments in the field of nanoscience and technology, with a focus on frontal application areas like silicon nanotechnologies, spintronics, quantum dots, carbon nanotubes, and protein-based devices as well as various biomolecular, clinical and medical applications. Topics include: the role of computational sciences in Si nanotechnologies and devices; few-electron quantum-dot spintronics; spintronics with metallic nanowires; Si/SiGe heterostructures in nanoelectronics; nanoionics and its device applications; and molecular electronics based on self-assembled monolayers. The volume also explores the self-assembly strategy of nanomanufacturing of hybrid devices; templated carbon nanotubes and the use of their cavities for nanomaterial synthesis; nanocatalysis; bifunctional nanomaterials for the imaging and treatment of cancer; protein-based nanodevices; bioconjugated quantum dots for tumor molecular imaging and profiling; modulation design of plasmonics for diagnostic and drug screening; theory of hydrogen storage in nanoscale materials; nanolithography using molecular films and processing; and laser applications in nanotechnology. The volume concludes with an analysis of the various risks that arise when using nanomaterials.
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19

(Editor), Hideaki Takayanagi, and Junsaku Nitta (Editor), eds. Realizing Controllable Quantum States: Proceedings of the Mesoscopic Superconductivity And Spintronics (Ms+s2004). World Scientific Publishing Company, 2005.

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20

Realizing controllable quantum states: Mesoscopic superconductivity and spintronics ©n the light of quantum computation : Atsugi, Kanagawa, Japan, 1-4 March 2004. Songapore: World Scientific, 2006.

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21

A Universe of Atoms, An Atom in the Universe. Springer, 2012.

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22

Nitta, J. Spin generation and manipulation based on spin-orbit interaction in semiconductors. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0013.

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This chapter focuses on the electron spin degree of freedom in semiconductor spintronics. In particular, the electrostatic control of the spin degree of freedom is an advantageous technology over metal-based spintronics. Spin–orbit interaction (SOI), which gives rise to an effective magnetic field. The essence of SOI is that the moving electrons in an electric field feel an effective magnetic field even without any external magnetic field. Rashba spin–orbit interaction is important since the strength is controlled by the gate voltage on top of the semiconductor’s two-dimensional electron gas. By utilizing the effective magnetic field induced by the SOI, spin generation and manipulation are possible by electrostatic ways. The origin of spin-orbit interactions in semiconductors and the electrical generation and manipulation of spins by electrical means are discussed. Long spin coherence is achieved by special spin helix state where both strengths of Rashba and Dresselhaus SOI are equal.
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23

Bauer, G. E. W. Spin Caloritronics. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0009.

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This chapter focuses on spin caloritronics, the field combining thermoelectrics with spintronics and nanomagnetism. Spin caloritronics is concerned with new physics related to spin, charge, and entropy/energy transport in materials and nanoscale structures and devices. Heat and spin effects are also coupled by the dissipation and noise associated with magnetization dynamics. Spin caloritronics lead to low power nan-scale devices and provide new strategies for waste heat recovery.
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24

Solymar, L., D. Walsh, and R. R. A. Syms. Magnetic materials. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198829942.003.0011.

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Macroscopic and microscopic theories of magnetic polarization are discussed. The origin of domains, domain walls, and of the hysteresis curve and the contrast between soft and hard magnetic materials are explained. The more important elements of the quantum theory of magnetism are discussed. The principles of the alignments in antiferromagnetic and ferromagnetic materials are explained. Magnetic resonance phenomena are discussed. Magnetoresistance and spintronics and their device prospects are also discussed at some length.
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25

Kavokin, Alexey V., Jeremy J. Baumberg, Guillaume Malpuech, and Fabrice P. Laussy. Polariton Devices. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198782995.003.0012.

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Polariton devices offer multiple advantages compared to conventional semiconductor devices. The bosonic nature of exciton polaritons offers opportunity of realisation of polariton lasers: coherent light sources based on bosonic condensates of polaritons. The final state stimulation of any transition feeding a polariton condensate has been used in many proposals such as for terahertz lasers based on polariton lasers. Furthermore, large coherence lengths of exciton-polaritons in microcavities open the way to realisation of polariton transport devices including transistors and logic gates. Being bosonic spin carriers, exciton-polaritons may be used in spintronic devices and polarisation switches. This chapter offers an overview on the existing proposals for polariton devices.
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26

Launay, Jean-Pierre, and Michel Verdaguer. Electrons in Molecules. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198814597.001.0001.

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The book treats in a unified way electronic properties of molecules (magnetic, electrical, photophysical), culminating with the mastering of electrons, i.e. molecular electronics and spintronics and molecular machines. Chapter 1 recalls basic concepts. Chapter 2 describes the magnetic properties due to localized electrons. This includes phenomena such as spin cross-over, exchange interaction from dihydrogen to extended molecular magnetic systems, and magnetic anisotropy with single-molecule magnets. Chapter 3 is devoted to the electrical properties due to moving electrons. One considers first electron transfer in discrete molecular systems, in particular in mixed valence compounds. Then, extended molecular solids, in particular molecular conductors, are described by band theory. Special attention is paid to structural distortions (Peierls instability) and interelectronic repulsions in narrow-band systems. Chapter 4 treats photophysical properties, mainly electron transfer in the excited state and its applications to photodiodes, organic light emitting diodes, photovoltaic cells and water photolysis. Energy transfer is also treated. Photomagnetism (how a photonic excitation modifies magnetic properties) is introduced. Finally, Chapter 5 combines the previous knowledge for three advanced subjects: first molecular electronics in its hybrid form (molecules connected to electrodes acting as wires, diodes, memory elements, field-effect transistors) or in the quantum computation approach. Then, molecular spintronics, using, besides the charge, the spin of the electron. Finally the theme of molecular machines is presented, with the problem of the directionality control of their motion.
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27

Sax, Alexander F. Potential Energy Surfaces: Proceedings of the Mariapfarr Workshop in Theoretical Chemistry. 1999.

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28

Maekawa, Sadamichi, Sergio O. Valenzuela, Eiji Saitoh, and Takashi Kimura, eds. Spin Current. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.001.0001.

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Since the discovery of the giant magnetoresistance effect in magnetic multilayers in 1988, a new branch of physics and technology, called spin-electronics or spintronics, has emerged, where the flow of electrical charge as well as the flow of electron spin, the so-called “spin current,” are manipulated and controlled together. The physics of magnetism and the application of spin current have progressed in tandem with the nanofabrication technology of magnets and the engineering of interfaces and thin films. This book aims to provide an introduction and guide to the new physics and applications of spin current, with an emphasis on the interaction between spin and charge currents in magnetic nanostructures.
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29

Glazov, M. M. Introduction. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198807308.003.0001.

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Creation, detection, and manipulation of spin degrees of freedom of electrons and nuclei, phenomena of spin relaxation, decoherence and dephasing, and processes of spin transfer between different subsystems are among the most important problems studied in semiconductor spintronics. These effects are most pronounced in systems with localized charge carriers, such as semiconductor quantum dots. This chapter contains the motivation behind and a brief review of the material presented in the book. It also clarifies the logic of the presentation in further chapters. Chapter 1 may be helpful to readers willing to find appropriate material without going through the whole book, as it contains a concise overview of the other chapters.
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30

Saitoh, E. Introduction. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0001.

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This chapter is an introduction to the concept of spin current, the detailed formulation of which is not simple by any means and is still a challenging undertaking. However, it is a useful and versatile concept that has given birth to a number of phenomena in condensed matter science and spintronics. There exist certain types of flow, carried by electrons, in condensed matter. This flow of electron charge or electric current has been developed and is now a vital contributor to how electronics is understood today. Since an electron carries both charge and spin, the existence of an electric current naturally implies the existence of a flow of spin. This flow is called a spin current.
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31

Busch, Paul. The Quantum Theory of Measurement. Springer, 2013.

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32

Ieda, J., and S. Maekawa. Spinmotive force. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0007.

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This chapter begins with Faraday’s law, which states that electromotive forces power everything by virtue of the charge e of an electron, and introduces spinmotive forces which reflect the magnetic moment of an electron. This motive force reflects the energy conservation requirements of the spin-torque transfer process that is at the heart of spintronics. The Stern-Gerlach experiment that used spin-dependent forces established the existence of spin. It is shown here that conservative forces would exist even if an electron was not charged, and do exist for uncharged excitations, such as magnons or phonons. Such forces are especially important in ferromagnetic materials where the spinmotive force commonly drives an electronic charge current due to the higher mobility of the majority electrons.
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33

Takanashi, K., and Y. Sakuraba. Spin polarization in magnets. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0005.

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This chapter explains how the exchange splitting between up- and down-spin bands in ferromagnets unexceptionally generates spin-polarized electronic states at the Fermi energy. The quantity of spin polarization P in ferromagnets is one of the important parameters for application in spintronics, since a ferromagnet having a higher P is able to generate larger various spin-dependent effects such as the magnetoresistance effect, spin transfer torque, spin accumulation, and so on. However, the spin polarizations of general 3d transition metals or alloys generally limit the size of spin-dependent effects. Thus,“‘half-metals” attract much interest as an ideal source of spin current and spin-dependent scattering because they possess perfectly spin-polarized conduction electrons due to the energy band gap in either the up- or down-spin channel at the Fermi level.
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34

Gustavsson, Fredrik. Properties of Fe/Znse Heterostructures: A Step Towards Semiconductor Spintronics (Comprehensive Summaries of Uppsala Dissertations from the Faculty Science and Technology, 713). Uppsala Universitet, 2002.

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35

Joachim, Christian. Atomic Scale Interconnection Machines: Proceedings of the 1st AtMol European Workshop Singapore 28th-29th June 2011. Springer, 2016.

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36

Uchida, K., R. Ramos, and E. Saitoh. Spin Seebeck effect. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0018.

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Chapter 18 This chapter discusses the spin Seebeck effect (SSE), which stands for the generation of a spin current, a flow of spinangular momentum, as a result of a temperature gradient in magnetic materials. In spintronics and spin caloritronics, the SSE is of crucial importance because it enables simple and versatile generation of a spin current from heat. Since the SSE is driven by thermally excited magnon dynaimcs, the thermal spin current can be generated not only from ferromagnetic conductors but also from insulators. Therefore, the SSE is applicable to “insulator-based thermoelectric conversion” which was impossible if only conventional thermoelectric technologies were used. In this chapter, after introducing basic characteristics and mechanisms of the SSE, important experimental progresses, such as the high-magnetic-field response of the SSE and the enhancement of the SSE in multilayer systems, are reviewed.
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37

Chaos and Order in Nature: Proceedings of the International Symposium on Synergetics at Schloß Elmau, Bavaria April 27 - May 2, 1981. Brand: Springer, 2011.

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38

Narlikar, A. V., ed. The Oxford Handbook of Small Superconductors. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780198738169.001.0001.

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This handbook examines cutting-edge developments in research and applications of small or mesoscopic superconductors, offering a glimpse of what might emerge as a giga world of nano superconductors. Contributors, who are eminent frontrunners in the field, share their insights on the current status and great promise of small superconductors in the theoretical, experimental, and technological spheres. They discuss the novel and intriguing features and theoretical underpinnings of the phenomenon of mesoscopic superconductivity, the latest fabrication methods and characterization tools, and the opportunities and challenges associated with technological advances. The book is organized into three parts. Part I deals with developments in basic research of small superconductors, including local-scale spectroscopic studies of vortex organization in such materials, Andreev reflection and related studies in low-dimensional superconducting systems, and research on surface and interface superconductivity. Part II covers the materials aspects of small superconductors, including mesoscopic effects in superconductor–ferromagnet hybrids, micromagnetic measurements on electrochemically grown mesoscopic superconductors, and magnetic flux avalanches in superconducting films with mesoscopic artificial patterns. Part III reviews the current progress in the device technology of small superconductors, focusing on superconducting spintronics and devices, barriers in Josephson junctions, hybrid superconducting devices based on quantum wires, superconducting nanodevices, superconducting quantum bits of information, and the use of nanoSQUIDs in the investigation of small magnetic systems.
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39

Joachim, Christian, and Nicolas Lorente. Architecture and Design of Molecule Logic Gates and Atom Circuits: Proceedings of the 2nd AtMol European Workshop. Springer, 2016.

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40

Blaquiere, A., G. Lochak, and S. Diner. Information Complexity and Control in Quantum Physics: Proceedings of the 4th International Seminar on Mathematical Theory of Dynamical Systems and Microphysics Udine, September 4-13 1985. Springer London, Limited, 2014.

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41

Zagoskin, Alexandre. Quantum Theory of Many-Body Systems. Springer, 2012.

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42

Zagoskin, Alexandre. Quantum Theory of Many-Body Systems: Techniques and Applications. Springer, 2012.

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43

Zagoskin, Alexandre. Quantum Theory of Many-Body Systems: Techniques and Applications. Springer, 2014.

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44

Zagoskin, Alexandre. Quantum Theory of Many-Body Systems: Techniques and Applications. Springer London, Limited, 2014.

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45

Endres, Manuel. Probing Correlated Quantum Many-Body Systems at the Single-Particle Level. Springer International Publishing AG, 2016.

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46

Probing Correlated Quantum Many-Body Systems at the Single-Particle Level. Springer, 2014.

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47

The Geometric Phase In Quantum Systems Foundations Mathematical Concepts And Applications In Molecular And Condensed Matter Physics. Springer, 2010.

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48

Brandt, Siegmund, Hans Dieter Dahmen, and T. Stroh. Interactive Quantum Mechanics: Quantum Experiments on the Computer. Springer, 2016.

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