TY - GEN AU - Girvin, Steven M. AU - Yang, Kun TI - Modern condensed matter physics SN - 9781107137394 AV - QC173.454 .G57 PY - 2019///] CY - Cambridge, U.K. PB - Cambridge University Press KW - Condensed matter KW - Electronic structure KW - Atomic structure N1 - Preface Acknowledgements 1. Overview of condensed matter physics 2. Spatial structure 3 Lattices and symmetries 4. Neutron scattering 5. Dynamics of lattice vibrations 6. Quantum theory of harmonic crystals 7. Electronic structure of crystals 8. Semiclassical transport theory 9. Semiconductors 10. Non-local transport in mesoscopic systems 11. Anderson localization 12. Integer quantum Hall effect 13. Topology and Berry phase 14. Topological insulators and semimetals 15. Interacting electrons 16. Fractional quantum Hall effect 17. Magnetism 18. Bose–Einstein condensation and superuidity 19. Superconductivity: basic phenomena and phenomenological theories 20. Microscopic theory of superconductivity Appendix A. Linear response theory Appendix B. The Poisson summation formula Appendix C. Tunneling and scanning tunneling microscopy Appendix D. Brief primer on topology Appendix E. Scattering matrices, unitarity and reciprocity Appendix F. Quantum entanglement in condensed matter physics Appendix G. Linear reponse and noise in electrical circuits Appendix H. Functional differentiation Appendix I. Low-energy effective hamiltonians Appendix J. Introduction to second quantization Bibliography Index N2 - Modern Condensed Matter Physics brings together the most important advances in the field of recent decades. It provides instructors teaching graduate-level condensed matter courses with a comprehensive and in-depth textbook that will prepare graduate students for research or further study as well as reading more advanced and specialized books and research literature in the field. This textbook covers the basics of crystalline solids as well as analogous optical lattices and photonic crystals, while discussing cutting-edge topics such as disordered systems, mesoscopic systems, many-body systems, quantum magnetism, Bose–Einstein condensates, quantum entanglement, and superconducting quantum bits. Students are provided with the appropriate mathematical background to understand the topological concepts that have been permeating the field, together with numerous physical examples ranging from the fractional quantum Hall effect to topological insulators, the toric code, and majorana fermions. Exercises, commentary boxes, and appendices afford guidance and feedback for beginners and experts alike.---Summary provided by the publisher ER -