超导、超流和凝聚体(牛津大学研究生教材系列)(Superconductivity Superfluids and Condensates)
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品牌: 詹姆斯
基本信息·出版社:科学出版社
·页码:186 页
·出版日期:2009年
·ISBN:7030236246/9787030236241
·条形码:9787030236241
·包装版本:1版
·装帧:平装
·开本:16
·正文语种:英语
·丛书名:牛津大学研究生教材系列
·外文书名:Superconductivity Superfluids and Condensates
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内容简介《超导、超流和凝聚体》包含三条主线:Bose-Einstein凝聚体(BEC),超流体和超导电性。书中首先建立专题的重要概念,然后介绍必要的数学方法。《超导、超流和凝聚体》从三个主题中最简单的BEC开始,首先全面回顾了Bose-Einstein理想气体的基础,然后详述了磁捕陷与原子冷却技术和稀化原子气体中的BEC。4He中的超流性较难理解,因为它是强相互作用量子流体。《超导、超流和凝聚体》介绍了超流性的主要物理现象,以及如何从宏观量子相干性与非对角长程序的主要概念得出超流现象。超导电性的理论分步加以阐述:先讨论较简单的London和GinzbergLandau理论及其主要应用,然后推导量子相干态的数学概念和Bardeen-Cooper-Shrieffer(BCS)理论。最后一章涉及较高深的话题,包括3He超流和特异超导体中的非常规Cooper对的证据。《超导、超流和凝聚体》不需要读者具备量子多体理论的知识,必要的数学概念会在需要处予以介绍。
编辑推荐《牛津大学研究生教材系列》介绍了物理学的主要领域的知识和柑关应用,旨在引导读者进入相关领域的前沿。丛书坚持深入浅出的写作风格,用丰富的示例、图表、总结加深读者埘内容的理解。书中附有习题供读者练习。
目录
1 Bose-Einstein凝聚体
1.1 引言
1.2 Bose-Einstein统计
1.3 Bose-Einstein凝聚
1.4 超冷原子气体中的BEC
进一步阅读材料
习题
2 超流4He
2.1 引言
2.2 经典与量子流体
2.3 宏观波函数
2.4 2He的超流性
2.5 环流量子化与涡旋
2.6 动量分布
2.7 准粒子激发
2.8 小结
进一步阅读材料
习题
3 超导电性
3.1 引言
3.2 金属中的导电
3.3 超导材料
3.4 零电阻率
3.5 Meissner-Ochsenfeld效应
3.6 完全抗磁性
3.7 第I类与第II类超导电性
3.8 London方程
3.9 London涡旋
进一步阅读材料
习题
4 Ginzburg-Landau模型
4.1 引言
4.2 凝聚能
4.3 体相变的Ginzburg-Landau理论
4.4 非均匀体系的Ginzburg-Landau理论
4.5 超导体的表面
4.6 磁场下的Ginzburg-Landau理论
4.7 规范对称性与对称性破缺
4.8 磁通量子化
4.9 Abrikosov磁通格子
4.10 热涨落
4.11 涡旋物质
4.12 小结
进一步阅读材料
习题
5 宏观相干态
5.1 引言
5.2 相干态
5.3 相干态与激光
5.4 玻色子量子场
5.5 非对角长程序
5.6 弱相互作用玻色气体
5.7 相干与超导体中的ODLRO
5.8 Josephson效应
5.9 宏观量子相干性
5.10 小结
进一步阅读材料
习题
6 超导电性的BCS理论
6.1 引言
6.2 电-声子相互作用
6.3 Cooper对
6.4 BCS波函数
6.5 平均场哈密顿量
6.6 BCS能隙与准粒子态
6.7 BCS理论的预测
进一步阅读材料
习题
7 超流3He与非常规超导电性
7.1 引言
7.2 3He的Fermi液体正常态
7.3 液态3He中的配对相互作用
7.4 3He的超流相
7.5 非常规超导体
进一步阅读材料
A 精选习题解答与提示
参考文献
索引
……[看更多目录]
序言Ever since their original discovery nearly 100 years ago, superconductors andsuperfluids have led to an incredible number of unexpected and surprising newphenomena. The theories which eventually explained superconductivity in met-als and superfluid 4He count among the greatest achievements in theoreticalmany-body physics, and have had profound implications in many other areas,such as in the construction of the "Higgs mechanism" and the standard modelof particle physics.Even now there is no sign that the pace of progress is slowing down. Indeedrecent years have seen renewed interest in the field in following the 1986 discov-ery of cuprate high temperature superconductivity and the 1995 announcementof Bose-Einstein condensation (BEC) in ultra-cold atomic gases. These break-throughs have tremendously widened the scope of the area of "low temperaturephysics" from 165 K (only about -100~C, a cold day at the North Pole) thehighest confirmed superconducting transition temperature ever recorded, tothe realm of nano-Kelvin in laser trapped condensates of atomic gases. Further-more an incredibly wide range of materials is now known to be superconducting.The field is no longer confined to the study of the metallic elements and theiralloys, but now includes the study of complex oxides, carbon-based materials(such as fullerene C60), organic conductors, rare earth based compounds (heavyfermion materials), and materials based on sulphur and boron (MgB2 supercon-ductivity was discovered in 2001 ). Commercial applications of superconductingtechnology are also increasing, albeit slowly. The LHC ring currently (in 2003)being installed at the CERN particle physics center is possible only becauseof considerable recent advances in superconducting magnet technology. Buteven this uses "traditional" superconducting materials. In principle, even morepowerful magnets could be built using novel high temperature superconductingmaterials, although these materials are difficult to work with and there are manytechnical problems still to be overcome.The goal of this book is to provide a clear and concise first introductionto this subject. It is primarily intended for use by final year undergraduatesand beginning postgraduates, whether in physics, chemistry, or materials sci-ence departments. Hopefully experienced scientists and others will also find itinteresting and useful.For the student, the concepts involved in superfluidity and superconductivitycan be difficult subject to master. It requires the use of many different elementsfrom thermodynamics, electromagnetism, quantum mechanics, and solid statephysics. Theories of superconductivity, such as the Bardeen Cooper Schrieffer(BCS) theory, are also most naturally written in the mathematics of quantumfield theory, a subject which is well beyond the usual undergraduate physicscurriculum. This book attempts to minimize the use of these advanced math-ematical techniques so as to make the subject more accessible to beginners.
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