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Books on the topic 'Superconducting thin film'

Author: Grafiati
Published: 6 September 2023

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1

H, Burness Arnold, ed. Superconducting thin films: New research. New York: Nova Science Publishers, 2008.

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2

R, Broussard Phillip, ed. Superconducting film devices. San Diego: Academic Press, 2000.

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3

Proch, D. Transparencies from the Workshop on Thin Film Coating Methods for Superconducting Accelerating Cavities. Hamburg: Deutsches Elektronen-Synchrotron DESY, MHF-SL Group, 2000.

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4

Roger, Stockbauer, Krishnaswamy S. V, Kurtz Richard L, and American Vacuum Society, eds. High TC superconducting thin films: Processing, characterization, and applications, Boston, MA 1989. New York: American Institute of Physics, 1990.

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5

1946-, Margaritondo Giorgio, Joynt Robert, Onellion Marshall, American Vacuum Society, and Topical Conference on High TC Superconducting Thin Films, Devices, and Applications (1988 : Atlanta, Ga.), eds. High Tc̳ superconducting thin films, devices, and applications, Atlanta, GA, 1988. New York, NY: American Institute of Physics, 1989.

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6

International, Symposium on Weak Superconductivity (7th 1994 Bratislava Slovak Republic). Proceedings of the Seventh International Symposium on Weak Superconductivity, June 6-10, 1994, Smolenice Castle, Slovak Republic. Bratislava, Slovak Republic: Dept. of Cryoelectronics, Institute of Electrical Engineering, 1994.

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7

Š, Beňačka, Darula M, and Kedro M, eds. Proceedings of the Sixth International Symposium on Weak Superconductivity, Smolenice, Czechoslovakia, 20-24 May 1991. Singapore: World Scientific, 1991.

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8

Haindl, Silvia. Iron-Based Superconducting Thin Films. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-75132-6.

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9

High-temperature superconducting thin films at microwave frequencies. Berlin: Springer, 1999.

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10

L, Shindé Subhash, and Rudman David Albert, eds. Interfaces in high-Tc superconducting systems. New York: Springer-Verlag, 1994.

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11

Bakar, Mizarina Abu. Microwave properties of high temperature superconducting thin films. Birmingham: University of Birmingham, 2003.

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12

Feng, Chen Jing, and United States. National Aeronautics and Space Administration., eds. Optical and electrical properties of thin superconducting films. Huntsville, Tex: Sam Houston State University, Dept. of Physics, 1990.

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13

L, Shindé Subhash, and Rudman David A, eds. Interfaces in high-T(subscript c) superconducting systems. New York: Springer-Verlag, 1994.

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14

Kromann, Rasmus. Deposition, characterization, and electronic applications of YBa2Cu3O7 thin films. Roskilde: Risø National Laboratory, 1992.

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15

Smithyman, John Robert Bruce. Magnetic flux noise in superconducting thin films and heterostructures. Birmingham: University of Birmingham, 1997.

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16

Davor, Pavuna, Bozovic Ivan, Society of Photo-optical Instrumentation Engineers., and Oxxel GmbH Bremen, eds. Superconducting and related oxides, physics and nanoengineering IV: 24-28 April 2000, Orlando, USA. Bellingham, Wash: SPIE, 2000.

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17

Ivan, Bozovic, Pavuna Davor, Society of Photo-optical Instrumentation Engineers., and Boeing Company, eds. Superconducting and related oxides: Physics and nanoengineering V : 8-11 July, 2002, Seattle, Washington, USA. Bellingham, Washington: SPIE, 2002.

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18

Lees, Simon Thomas. Synthesis of novel superconducting thin films by pulsed laser ablation. Birmingham: University of Birmingham, 1997.

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19

Avenhaus, Beate. Characterisation of high temperature superconducting thin films and their microwave applications. Birmingham: University of Birmingham, 1996.

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20

J, Valco George, and United States. National Aeronautics and Space Administration., eds. Sequentially evaporated thin Y-Ba-Co-O superconducting films on microwave substrates. [Washington, DC]: National Aeronautics and Space Administration, 1989.

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21

N, Peters P., and George C. Marshall Space Flight Center., eds. Characterizations of electrical properties of high Tc superconducting materials: Center director's discretionary fund final report. [Marshall Space Flight Center, AL]: National Aeronautics and Space Administration, George C. Marshall Space Flight Center, 1989.

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22

Davor, Pavuna, Bozovic Ivan, Society of Photo-optical Instrumentation Engineers., and Oxxel GmbH Bremen, eds. Superconducting and related oxides, physics and nanoengineering III: 20-24 July, 1998, San Diego, California. Bellingham, Wash: SPIE, 1998.

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23

United States. National Aeronautics and Space Administration., ed. Microwave properties of high transition temperature superconducting thin films: Final technical report to the NASA Lewis Research Center. [Washington, D.C.?: National Aeronautics and Space Administration, 1991.

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24

Dong, Zi-Wen. High-Tc Superconducting Thin Film Devices. Delft Univ Pr, 1995.

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25

Sequentially evaporated thin film YBa₂Cu₃O₇₋x superconducting microwave ring resonater. [Washington, D.C.]: NASA, 1990.

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26

T, Venkatesan, and Society of Photo-optical Instrumentation Engineers., eds. Processing of films for high Tc superconducting electronics: 10-12 October 1989, Santa Clara, California. Bellingham, Wash., USA: SPIE, 1990.

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27

Joynt, Robert, and Giorgio Margaritondo. High-Tc Superconducting Thin Films, Devices, and Applications (Aip Conference Proceedings). AIP Press, 1989.

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28

(Editor), Roger L. Stockbauer, S. V. Krishnaswamy (Editor), and Richard L. Kurtz (Editor), eds. High Tc Superconducting Thin Films: Processing, Characterization, and Applications: Boston, MA 1989 (AIP Conference Proceedings / American Vacuum Society Series). American Institute of Physics, 1998.

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29

Haindl, Silvia. Iron-Based Superconducting Thin Films. Springer International Publishing AG, 2021.

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30

Koblischka, M. R. Growth and Characterization of HTSc Nanowires and Nanoribbons. Edited by A. V. Narlikar. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780198738169.013.11.

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This article describes the fabrication of high-temperature superconducting nanowires and their characterization by magnetic and electric transport measurements. In the literature, nanowires of high-temperature superconductors (HTSc) are obtained by means of lithography, using thin film material as a base. However, there are two main problems with this approach: first, the substrate often influences the HTSc nanowire, and second, only electric transport measurements can be performed. This article explains how nanowires and nanobelts of high-temperature superconducting cuprates can be prepared by the template method and by electrospinning. It also considers the possibilities for employing substrate-free HTSc nanowires as building blocks to realize new, nanoporous bulk superconducting materials for a variety of applications.
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31

Shinde, Subhash. Interfaces in High-Tc Superconducting Systems. Springer, 2013.

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32

Boychev, Vladimir. Far-infrared studies of superconducting thin films and Fabry-Perot resonators made of such films. 2001.

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33

Young, Martin George. Flux pinning in superconducting thin films of Y1Ba2Cu3O7-x. 1988.

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34

Hall, Michael Matthews. A search for new substrate materials for high temperature superconducting thin films. 1996.

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35

Th©♭, Stephens Sin-Tsun. Studies of laser-target interactions in pulsed excimer laser evaporation of superconducting oxides and other metal oxides. 1993.

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36

National Aeronautics and Space Administration (NASA) Staff. Microwave Properties of High Transition Temperature Superconducting Thin Films. Independently Published, 2018.

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37

Albert C. Nunneley John K. Lauer. Transition Time from Resistive to Superconducting State for Thin Indium Films. Creative Media Partners, LLC, 2021.

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38

Photoresponse of YBa₂Cu₃O₇₋[delta] granular and epitaxial superconducting thin films. [Washington, D.C.]: NASA, 1990.

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39

Emerging applications of high temperature superconductors for space communciations. [Washington, DC]: National Aeronautics and Space Administration, 1990.

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40

Motta, M., A. V. Silhanek, and W. A. Ortiz. Magnetic Flux Avalanches in Superconducting Films with Mesoscopic Artificial Patterns. Edited by A. V. Narlikar. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780198738169.013.13.

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This article examines the practical problem of thermally driven high-speed flux avalanches occurring in superconducting thin films with mesoscopic artificial patterns. The thin films are synthesized with artificial pins in the form of sub-micrometric antidots (ADs). The article first provides an overview of magnetic flux avalanches in superconductors, with particular emphasis on thermally driven avalanches, before discussing the occurrence and morphology of flux avalanches in superconducting thin films comprised of AD arrays. It analyses the influence of lattice symmetry and different AD geometries on the guidance and consequently the branching of flux avalanches. It also explores how artificial pinning centers inserted in superconducting films affect vortex dynamics.
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41

Nishio, T., Y. Hata, S. Okayasu, J. Suzuki, S. Nakayama, A. Nagata, A. Odawara, K. Chinone, and K. Kadowaki. Scanning SQUID microscope study of vortex states and phases in superconducting mesoscopic dots, antidots, and other structures. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.11.

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This article investigates vortex states and phases in superconducting mesoscopic dots, antidots, and other structures using a scanning superconducting quantum interference device (SQUID) microscope. It begins with an introduction to the phenomenology of superconductivity and the fundamentals of vortex confinement in mesoscopic superconductors. It then provides a background on the SQUID microscope, followed by a discussion of how a high-resolution scanning SQUID microscope was developed. It also describes what the scanning SQUID microscopy revealed about quantized flux in superconducting rings, as well as vortex confinement in microscopic superconducting disks, triangles, and squares. Finally, it presents the results of direct observation of an extended penetration depth in thin films and vortex states in high-temperature superconductors.
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42

Kokubo, N., S. Okayasu, and K. Kadowaki. Multi-Vortex States in Mesoscopic Superconductors. Edited by A. V. Narlikar. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780198738169.013.3.

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This article investigates multi-vortex states in mesoscopic amorphous superconductors with different geometries by means of scanning SQUID microscopy. It first describes the setup of the scanning SQUID microscope used in magnetic imaging of superconducting vortices before discussing the physical properties of amorphous superconducting thin films. It then presents the results of experiments showing the formation of multi-vortex states in mesoscopic dots of weak pinning, amorphous MoGe thin films, along with the formation of vortex polygons and concentric vortex rings in mesoscopic disks. It also considers the concept of multiple vortex shells and its applicability to vortex patterns observed in mesoscopic circle and square dots. The article highlights some of the key features of mesoscopic superconducting dots, including commensurability effect, multiple shell structures, repeated packing sequences, inclusion structural hierarchy, and pinning effect.
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43

Kanda, A., Y. Ootuka, K. Kadowaki, and F. M. Peeters. Novel superconducting states in nanoscale superconductors. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533046.013.19.

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This article describes novel superconducting states in nanoscale superconductors. It first considers characteristic lengths in superconductors and vortices in mesoscopic superconductors before discussing trends in superconductivity research, which is closely related to recent progress in nanotechnology. It then explains the theoretical methods used for the study of mesoscopic superconducting states, along with theoretical predictions of vortex states in thin mesoscopic superconducting films. It also looks at experimental techniques used for the detection of vortices, including direct visualization of the vortex positions and indirect methods such as the multiple-small-tunnel-junction method, and experimental detection of mesoscopic vortex states in disks and squares. Finally, it evaluates one-dimensional vortex in mesoscopic rings.
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44

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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45

Determination of surface resistance and magnetic penetration depth of superconducting YBa₂Cu₃O₇-[delta] thin films by microwave power transmission measurements. [Washington, DC]: National Aeronautics and Space Administration, 1990.

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