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Functional Nanostructures and Metamaterials for Superconducting Spintronics: From Superconducting Qubits to Self-Organized Nanostructures 1st ed. 2018 [Kietas viršelis]

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  • Formatas: Hardback, 270 pages, aukštis x plotis: 235x155 mm, weight: 4297 g, 111 Illustrations, color; 37 Illustrations, black and white; XVII, 270 p. 148 illus., 111 illus. in color., 1 Hardback
  • Serija: NanoScience and Technology
  • Išleidimo metai: 03-Jul-2018
  • Leidėjas: Springer International Publishing AG
  • ISBN-10: 3319904809
  • ISBN-13: 9783319904801
Kitos knygos pagal šią temą:
Functional Nanostructures and Metamaterials for Superconducting Spintronics: From Superconducting Qubits to Self-Organized Nanostructures 1st ed. 2018Didesnis paveikslėlis
  • Formatas: Hardback, 270 pages, aukštis x plotis: 235x155 mm, weight: 4297 g, 111 Illustrations, color; 37 Illustrations, black and white; XVII, 270 p. 148 illus., 111 illus. in color., 1 Hardback
  • Serija: NanoScience and Technology
  • Išleidimo metai: 03-Jul-2018
  • Leidėjas: Springer International Publishing AG
  • ISBN-10: 3319904809
  • ISBN-13: 9783319904801
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9783319904801.html
Raktažodžiai:
This book demonstrates how the new phenomena in the nanometer scale serve as the basis for the invention and development of novel nanoelectronic devices and how they are used for engineering nanostructures and metamaterials with unusual properties. It discusses topics such as superconducting spin-valve effect and thermal spin transport, which are important for developing spintronics; fabrication of nanostructures from antagonistic materials like ferromagnets and superconductors, which lead to a novel non-conventional  FFLO-superconducting state; calculations of functional nanostructures with an exotic triplet superconductivity, which are the basis for novel nanoelectronic devices, such as superconducting spin valve, thin-film superconducting quantum interference devices (SQUIDs) and memory-elements (MRAM). Starting with theoretical chapters about triplet superconductivity, the book then introduces new ideas and approaches in the fundamentals of superconducting electronics. It presents various quantum devices based on the new theoretical approaches, demonstrating the enormous potential of the electronics of 21st century - spintronics.





The book is useful for a broad audience, including researchers, engineers, PhD graduates, students and others wanting to gain insights into the frontiers of nanoscience.
Basic Superconducting Spin Valves
1(30)
V. N. Kushnir
Anatolie Sidorenko
L. R. Tagirov
M. Yu. Kupriyanov
1 Introduction
2(2)
2 Superconductor-Metallic Ferromagnet Proximity Effect
4(2)
3 Elementary Superconducting Spin Valve: Diffusive Limit
6(4)
4 Elementary Spin Valve with Strong Ferromagnets
10(9)
4.1 Normal and Inverse Spin Valve Effects in the Elementary Structures
10(1)
4.2 Superconducting Spin Valve Effect and the Domain Structures of Ferromagnets
11(3)
4.3 Theory of Spin Valve in the Clean Limit
14(1)
4.4 Parametric Spin Valve
15(4)
5 Superconducting Spin Valve Effect in the S/F1/N/F2 Structures
19(3)
6 Discussion and Conclusion
22(2)
References
24(7)
Superconducting Triplet Proximity and Josephson Spin Valves
31(18)
L. R. Tagirov
M. Yu. Kupriyanov
V. N. Kushnir
Anatolie Sidorenko
1 Introduction
32(1)
2 Superconductor-Ferromagnet Proximity Spin Valves
33(2)
3 Superconducting Spin-Valve Effect in the S/F1/N/F2 Structures
35(5)
4 Josephson Spin Valves with Ferromagnetic Weak Links
40(4)
References
44(5)
Compact Josephson Φ-Junctions
49(24)
S. V. Bakurskiy
N. V. Klenov
I. I. Soloviev
Anatolie Sidorenko
M. Yu. Kupriyanov
A. A. Golubov
1 Introduction
50(2)
2 Model
52(3)
3 Ramp- and Overlap-Type Geometries
55(12)
4 Discussion and Conclusion
67(2)
References
69(4)
Magnetic Proximity Effect and Superconducting Triplet Correlations at the Heterostructure of Cuprate Superconductor and Oxide Spin Valve
73(18)
K. Y. Constantinian
G. A. Ovsyannikov
V. V. Demidov
Yu. N. Khaydukov
1 Introduction
74(1)
2 Experimental
75(2)
3 Magnetic Proximity Effect
77(5)
4 Superconducting Triplet Correlations
82(5)
5 Conclusion
87(1)
References
88(3)
Nanodevices with Normal Metal---Insulator---Superconductor Tunnel Junctions
91(26)
M. Tarasov
V. Edelman
1 Introduction: The NIS Junction at a Glance
92(1)
2 Fabrication Technology
93(2)
3 Terahertz Band Conventional SINIS Bolometer
95(5)
4 Mechanisms of Energy Relaxation and Time Scale
100(5)
5 Electron Cooling of Absorber and Overheating of Superconductor
105(2)
6 NIS Thermometer
107(2)
7 Andreev Current and Hot Electron Traps
109(4)
8 Current Response, Quantum Efficiency, and Thermalization
113(1)
9 Conclusion
114(1)
References
115(2)
Multichroic Polarization Sensitive Planar Antennas with Resonant Cold-Electron Bolometers for Cosmology Experiments
117(12)
L. S. Kuzmin
A. V. Chiginev
1 Introduction. ESA Requirements
117(1)
2 Seashell Antenna
118(3)
3 Cross-Slot Antenna
121(4)
4 Comparison and Discussion
125(1)
References
126(3)
Passive Millimeter-Wave Imaging Technology for Concealed Contraband Detection
129(32)
Jing-Hui Qiu
Jiaran Qi
Nan-nan Wang
Aleksandr Denisov
1 Introduction
129(1)
2 Theory of Passive Millimeter-Wave Imaging
130(5)
2.1 Planck's Radiation Law-Blackbody Radiation Detection Theory
131(3)
2.2 Radiation Temperature Transfer Model of the Passive Millimeter-Wave Near-Field Imaging
134(1)
3 Millimeter-Wave Radiometer
135(6)
3.1 Key Technical Parameters of Millimeter-Wave Radiometer
135(2)
3.2 Millimeter-Wave Direct Detection Radiometer
137(2)
3.3 Calibration Method for the Radiometer Array Adopted in the Passive Millimeter-Wave Imaging System
139(2)
4 Passive Millimeter-Wave Near-Field Imaging Feed Antenna
141(5)
5 Quasi-optical Theory and Focusing Antenna for Passive Millimeter-Wave Near-Field Imaging
146(6)
5.1 Quasi-optics Design Method
146(2)
5.2 The Design of the Optical System Parameters
148(1)
5.3 Design of Lens Curvature
149(3)
6 Passive Millimeter-Wave Near-Filed Imaging System
152(6)
6.1 20-Channel FPA System for Hidden Object Detection Under Human Clothing
153(1)
6.2 High Spatial Resolution 70-Channel FPA System for Concealed Object Detection Under Human Clothing
154(4)
References
158(3)
Coupled Spin and Heat Transport in Superconductor Hybrid Structures
161(14)
Detlef Beckmann
1 Introduction
161(1)
2 Nonlocal Spin Transport
162(2)
3 Spin-Dependent Thermoelectric Effects
164(4)
4 Possible Applications
168(4)
4.1 Thermometry
168(2)
4.2 Cooling
170(2)
5 Conclusion and Outlook
172(1)
References
172(3)
Easing in Circuit Quantum Electrodynamics
175(20)
G. Oelsner
E. Il'ichev
1 Introduction
175(1)
2 Requirements for Lasing
176(2)
3 Circuit QED with Superconducting Quantum Systems
178(4)
4 Lasing by Single Superconducting Artificial Atoms
182(10)
4.1 Standard Lasing Scheme
182(1)
4.2 Dressed-State Lasing
183(6)
4.3 Landau-Zener-Stiickelberg Lasing
189(3)
5 Summary and Conclusion
192(1)
References
193(2)
Topology-Driven Effects in Advanced Micro- and Nanoarchitectures
195(26)
V. M. Fomin
1 Introduction
196(1)
2 Topologic Effects in Quantum Rings by Virtue of Doubly Connectedness
197(3)
3 Topologic Effects in Mobius Rings
200(6)
4 Superconducting Vortices: Topological Defects in Micro- and Nanoarchitectures
206(5)
5 Topologic States of Light in Microcavities
211(6)
5.1 Resonant Modes of Light in a Mobius-Ring Resonator
211(2)
5.2 Optical Spin-Orbit Coupling and Non-Abelian Evolution of Light in Asymmetric Microcavities
213(1)
5.3 Non-Abelian Evolution of Light Polarization
214(3)
6 Conclusions
217(1)
References
218(3)
Functional Magnetic Metamaterials for Spintronics
221(26)
Yu. P. Sharaevsky
A. V. Sadovnikov
E. N. Beginin
A. Yu. Sharaevskaya
S. E. Sheshukova
S. A. Nikitov
1 Introduction
222(2)
2 Spin Waves in Width-Modulated Magnonic Crystal
224(4)
3 Defect Spin-Wave Modes Coupling in Magnonic Crystals
228(5)
4 Multimode Surface Magnetostatic Wave Propagation in Irregular Planar Magnonic Structure
233(6)
5 Transverse Mode Coupling in Confined Multiferroics
239(4)
6 Conclusion
243(1)
References
244(3)
Quantum Transport, Superconductivity, and Weak Ferromagnetism at Bicrystal Interfaces of Bi and 3D Topological Insulator BiSb
247(18)
Fiodor M. Muntyanu
Andrzej Gilewski
Andrzej J. Zaleski
Vitalie Chistol
Viorel Munteanu
Krzysztof Rogacki
Anatolie Sidorenko
1 Introduction
248(2)
2 Samples and Experimental Procedure
250(1)
3 Results and Discussion
251(11)
3.1 Fermi Surface Rearrangement in Bi and BiixSbx (x < 0.18) Bicrystals
251(3)
3.2 High-Field Quantum Transport in Bi and BiSb Bicrystals
254(2)
3.3 Superconductivity and Weak Ferromagnetism at the Interface of Bicrystals of Bi and 3D Topological Insulator BiSb
256(6)
4 Conclusions
262(1)
References
262(3)
Index 265
Anatolie Sidorenko obtained his doctoral degree in 1979 at the Institute for Low Temperatures of Ukrainian Academy of Sciences, Kharkov, and  habilitation degree  in 1991 at the Institute of Applied Physics of Moldavian Academy of Sciences, Chisinau. He is currently Director of the Institute of Electronic Engineering and Nanotechnologies, Chisinau, Moldova. His research interest focus on properties of low dimensional systems, layered nanostructures and hybrids uperconductor/ferromagnet with emphasis on spintronics, superconductivity, transport and magnetic phenomena in functional nanostructures. Anatolie Sidorenko has edited the book Fundamentals of Superconducting Nanoelectronics (Springer, 2011) and co-edited Nanoscale Phenomena Fundamentals and Applications (Springer, 2009), he is associate editor of the Beilstein Journal of Nanotechnology.  Anatolie Sidorenko is a member of the Moldavian Academy of Sciences since 2012 and DPG member since 2001.