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Theory of High Temperature Superconductivity (2001)
Theory of High Temperature Superconductivity

Theory of High Temperature Superconductivity

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"Theory of High Temperature Superconductivity" by S. Fujita, S. Godoy is a mathematics book and learning resource focused on Devices & Sensors. Best for teachers, students, and readers looking for stronger mathematical understanding.

Flux quantization experiments indicate that the carriers, Cooper pairs (pairons), in the supercurrent have charge magnitude 2e, and that they move independently. Josephson interference in a Superconducting Quantum Int- ference Device (SQUID) shows that the centers of masses (CM) of pairons move as bosons with a linear dispersion relation. Based on this evidence we develop a theory of superconductivity in conventional and mate- als from a unified point of view. Following Bardeen, Cooper and Schrieffer (BCS) we regard the phonon exchange attraction as the cause of superc- ductivity. For cuprate superconductors, however, we take account of both optical- and acoustic-phonon exchange. BCS started with a Hamiltonian containing “electron” and “hole” kinetic energies and a pairing interaction with the phonon variables eliminated. These “electrons” and “holes” were introduced formally in terms of a free-electron model, which we consider unsatisfactory. We define “electrons” and “holes” in terms of the cur- tures of the Fermi surface. “Electrons” (1) and “holes” (2) are different and so they are assigned with different effective masses: Blatt, Schafroth and Butler proposed to explain superconductivity in terms of a Bose-Einstein Condensation (BEC) of electron pairs, each having mass M and a size. The system of free massive bosons, having a quadratic dispersion relation: and moving in three dimensions (3D) undergoes a BEC transition at where is the pair density.
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Best For: Researchers and students interested in the physics and materials science of superconductivity.
Focus: Theoretical development of superconductivity based on experimental evidence of Cooper pairs and their behavior.
Covers: Flux quantization, Cooper pairs (pairons), Josephson interference, and the movement of pairons as bosons with linear dispersion.
Why It Matters: Provides a unified theoretical framework for understanding superconductivity in conventional and other materials, grounded in experimental observations.

"Theory of High Temperature Superconductivity" by S. Fujita, S. Godoy is a mathematics book and learning resource focused on Devices & Sensors. Best for teachers, students, and readers looking for stronger mathematical understanding.

Topic: Devices & Sensors

Author: S. Fujita, S. Godoy

Who this is for:

  • Teachers and classroom instructors
  • Students building subject mastery
  • Readers looking for practical learning support

Why this book matters: It stands out as a practical math resource that helps explain concepts, strengthen problem-solving, and support classroom or independent learning.

Flux quantization experiments indicate that the carriers, Cooper pairs (pairons), in the supercurrent have charge magnitude 2e, and that they move independently. Josephson interference in a Superconducting Quantum Int- ference Device (SQUID) shows that the centers of masses (CM) of pairons move as bosons with a linear dispersion relation. Based on this evidence we develop a theory of superconductivity in conventional and mate- als from a unified point of view. Following Bardeen, Cooper and Schrieffer (BCS) we regard the phonon exchange attraction as the cause of superc- ductivity. For cuprate superconductors, however, we take account of both optical- and acoustic-phonon exchange. BCS started with a Hamiltonian containing “electron” and “hole” kinetic energies and a pairing interaction with the phonon variables eliminated. These “electrons” and “holes” were introduced formally in terms of a free-electron model, which we consider unsatisfactory. We define “electrons” and “holes” in terms of the cur- tures of the Fermi surface. “Electrons” (1) and “holes” (2) are different and so they are assigned with different effective masses: Blatt, Schafroth and Butler proposed to explain superconductivity in terms of a Bose-Einstein Condensation (BEC) of electron pairs, each having mass M and a size. The system of free massive bosons, having a quadratic dispersion relation: and moving in three dimensions (3D) undergoes a BEC transition at where is the pair density.

AuthorS. Fujita, S. Godoy
PublisherSpringer
Published2010-12-04
ISBN-139789048158836
BindingPaperback
Pages374
LanguageEnglish
SubjectsScience
TopicDevices & Sensors
SeriesFundamental Theories of Physics

Format: Paperback

Length: 374 pages

Language: English

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