Topological Insulators: Fundamentals and PerspectivesJohn Wiley & Sons, 8 апр. 2015 г. - Всего страниц: 432 There are only few discoveries and new technologies in physical sciences that have the potential to dramatically alter and revolutionize our electronic world. Topological insulators are one of them. The present book for the first time provides a full overview and in-depth knowledge about this hot topic in materials science and condensed matter physics. Techniques such as angle-resolved photoemission spectrometry (ARPES), advanced solid-state Nuclear Magnetic Resonance (NMR) or scanning-tunnel microscopy (STM) together with key principles of topological insulators such as spin-locked electronic states, the Dirac point, quantum Hall effects and Majorana fermions are illuminated in individual chapters and are described in a clear and logical form. Written by an international team of experts, many of them directly involved in the very first discovery of topological insulators, the book provides the readers with the knowledge they need to understand the electronic behavior of these unique materials. Being more than a reference work, this book is essential for newcomers and advanced researchers working in the field of topological insulators. |
Содержание
Materials and Structures | 101 |
Electronic Characterization and Transport Phenomena | 265 |
401 | |
EULA | 408 |
Другие издания - Просмотреть все
Topological Insulators: Fundamentals and Perspectives Frank Ortmann,Stephan Roche,Sergio O. Valenzuela Ограниченный просмотр - 2015 |
Topological Insulators: Fundamentals and Perspectives Frank Ortmann,Stephan Roche,Sergio O. Valenzuela Ограниченный просмотр - 2015 |
Часто встречающиеся слова и выражения
Andreev reflection ARPES atomic backscattering band inversion band structure bilayer BioSea Brillouin zone bulk band bulk bandgap bulk conduction calculations carrier Cava Chen chirality conduction band crystals density Dirac cone Dirac fermions Dirac point dispersion doped electronic structure energy experimental Fermi level Fermi surface ferromagnetic function graphene 𝐺𝑊 Hall effect Hamiltonian Hasan HgTe Hsieh hybridization interaction interface 𝐤 Kondo layer Lett magnetic field Majorana fermions materials measurements momentum nanostructures nanowires nontrivial observed parity phase transition Phys predicted pseudopotentials QAHE quantized quantum spin quantum spin Hall quasiparticle sample SdH oscillations semimetal shown in Figure spin polarization spin texture spin–orbit substrate superconducting surface band surface electrons temperature tetradymite thin films topological insulator topological phase topological surface transport TRIM tunneling valence band Wang Zhang 𝛼