Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /

Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /

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In 1987 a major breakthrough occurred in materials science. A new family of materials was discovered that became superconducting above the temperature at which nitrogen gas liquifies, namely, 77 K or –196°C. Within months of the discovery, a wide variety of experimental techniques were brought to bear in order to measure the properties of these materials and to gain an understanding of why they superconduct at such high temperatures. Among the techniques used were electromagnetic absorption in both the normal and the superconducting states. The measurements enabled the determination of a wide variety of properties, and in some instances led to the observation of new effects not seen by other measu- ments, such as the existence of weak-link microwave absorption at low dc magnetic fields. The number of different properties and the degree of detail that can be obtained from magnetic field- and temperature-dependent studies of electromagnetic abso- tion are not widely appreciated. For example, these measurements can provide information on the band gap, critical fields, the H–T irreversibility line, the amount of trapped flux, and even information about the symmetry of the wave function of the Cooper pairs. It is possible to use low dc magnetic field-induced absorption of microwaves with derivative detection to verify the presence of superconductivity in a matter of minutes, and the measurements are often more straightforward than others. For example, they do not require the physical contact with the sample that is necessary when using four-probe resistivity to detect superconductivity.

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Main Authors: Owens, Frank J. author., Poole, Charles P. author., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Boston, MA : Springer US, 2002
Subjects:Materials science., Condensed matter., Optical materials., Electronic materials., Materials Science., Characterization and Evaluation of Materials., Condensed Matter Physics., Optical and Electronic Materials.,
Online Access:http://dx.doi.org/10.1007/b118216
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spelling KOHA-OAI-TEST:2095912018-07-30T23:41:07ZElectromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] / Owens, Frank J. author. Poole, Charles P. author. SpringerLink (Online service) textBoston, MA : Springer US,2002.engIn 1987 a major breakthrough occurred in materials science. A new family of materials was discovered that became superconducting above the temperature at which nitrogen gas liquifies, namely, 77 K or –196°C. Within months of the discovery, a wide variety of experimental techniques were brought to bear in order to measure the properties of these materials and to gain an understanding of why they superconduct at such high temperatures. Among the techniques used were electromagnetic absorption in both the normal and the superconducting states. The measurements enabled the determination of a wide variety of properties, and in some instances led to the observation of new effects not seen by other measu- ments, such as the existence of weak-link microwave absorption at low dc magnetic fields. The number of different properties and the degree of detail that can be obtained from magnetic field- and temperature-dependent studies of electromagnetic abso- tion are not widely appreciated. For example, these measurements can provide information on the band gap, critical fields, the H–T irreversibility line, the amount of trapped flux, and even information about the symmetry of the wave function of the Cooper pairs. It is possible to use low dc magnetic field-induced absorption of microwaves with derivative detection to verify the presence of superconductivity in a matter of minutes, and the measurements are often more straightforward than others. For example, they do not require the physical contact with the sample that is necessary when using four-probe resistivity to detect superconductivity.The Superconducting State -- The New Superconductors -- Experimental Methods and Complementary Techniques -- Electromagnetic Absorption in the Normal State -- Zero Magnetic Field Microwave Absorption -- Low Magnetic Field-Induced Microwave Absorption -- Electromagnetic Absorption Due to Vortex Motion -- Infrared and Optical Absorption -- Applications.In 1987 a major breakthrough occurred in materials science. A new family of materials was discovered that became superconducting above the temperature at which nitrogen gas liquifies, namely, 77 K or –196°C. Within months of the discovery, a wide variety of experimental techniques were brought to bear in order to measure the properties of these materials and to gain an understanding of why they superconduct at such high temperatures. Among the techniques used were electromagnetic absorption in both the normal and the superconducting states. The measurements enabled the determination of a wide variety of properties, and in some instances led to the observation of new effects not seen by other measu- ments, such as the existence of weak-link microwave absorption at low dc magnetic fields. The number of different properties and the degree of detail that can be obtained from magnetic field- and temperature-dependent studies of electromagnetic abso- tion are not widely appreciated. For example, these measurements can provide information on the band gap, critical fields, the H–T irreversibility line, the amount of trapped flux, and even information about the symmetry of the wave function of the Cooper pairs. It is possible to use low dc magnetic field-induced absorption of microwaves with derivative detection to verify the presence of superconductivity in a matter of minutes, and the measurements are often more straightforward than others. For example, they do not require the physical contact with the sample that is necessary when using four-probe resistivity to detect superconductivity.Materials science.Condensed matter.Optical materials.Electronic materials.Materials Science.Characterization and Evaluation of Materials.Condensed Matter Physics.Optical and Electronic Materials.Springer eBookshttp://dx.doi.org/10.1007/b118216URN:ISBN:9780306470820
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Materials science.
Condensed matter.
Optical materials.
Electronic materials.
Materials Science.
Characterization and Evaluation of Materials.
Condensed Matter Physics.
Optical and Electronic Materials.
Materials science.
Condensed matter.
Optical materials.
Electronic materials.
Materials Science.
Characterization and Evaluation of Materials.
Condensed Matter Physics.
Optical and Electronic Materials.
spellingShingle Materials science.
Condensed matter.
Optical materials.
Electronic materials.
Materials Science.
Characterization and Evaluation of Materials.
Condensed Matter Physics.
Optical and Electronic Materials.
Materials science.
Condensed matter.
Optical materials.
Electronic materials.
Materials Science.
Characterization and Evaluation of Materials.
Condensed Matter Physics.
Optical and Electronic Materials.
Owens, Frank J. author.
Poole, Charles P. author.
SpringerLink (Online service)
Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /
description In 1987 a major breakthrough occurred in materials science. A new family of materials was discovered that became superconducting above the temperature at which nitrogen gas liquifies, namely, 77 K or –196°C. Within months of the discovery, a wide variety of experimental techniques were brought to bear in order to measure the properties of these materials and to gain an understanding of why they superconduct at such high temperatures. Among the techniques used were electromagnetic absorption in both the normal and the superconducting states. The measurements enabled the determination of a wide variety of properties, and in some instances led to the observation of new effects not seen by other measu- ments, such as the existence of weak-link microwave absorption at low dc magnetic fields. The number of different properties and the degree of detail that can be obtained from magnetic field- and temperature-dependent studies of electromagnetic abso- tion are not widely appreciated. For example, these measurements can provide information on the band gap, critical fields, the H–T irreversibility line, the amount of trapped flux, and even information about the symmetry of the wave function of the Cooper pairs. It is possible to use low dc magnetic field-induced absorption of microwaves with derivative detection to verify the presence of superconductivity in a matter of minutes, and the measurements are often more straightforward than others. For example, they do not require the physical contact with the sample that is necessary when using four-probe resistivity to detect superconductivity.
format Texto
topic_facet Materials science.
Condensed matter.
Optical materials.
Electronic materials.
Materials Science.
Characterization and Evaluation of Materials.
Condensed Matter Physics.
Optical and Electronic Materials.
author Owens, Frank J. author.
Poole, Charles P. author.
SpringerLink (Online service)
author_facet Owens, Frank J. author.
Poole, Charles P. author.
SpringerLink (Online service)
author_sort Owens, Frank J. author.
title Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /
title_short Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /
title_full Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /
title_fullStr Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /
title_full_unstemmed Electromagnetic Absorption in the Copper Oxide Superconductors [electronic resource] /
title_sort electromagnetic absorption in the copper oxide superconductors [electronic resource] /
publisher Boston, MA : Springer US,
publishDate 2002
url http://dx.doi.org/10.1007/b118216
work_keys_str_mv AT owensfrankjauthor electromagneticabsorptioninthecopperoxidesuperconductorselectronicresource
AT poolecharlespauthor electromagneticabsorptioninthecopperoxidesuperconductorselectronicresource
AT springerlinkonlineservice electromagneticabsorptioninthecopperoxidesuperconductorselectronicresource
_version_ 1756268680159690752

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