Theory of Magnetoelectric Properties of 2D Systems
Nonfiction, Science & Nature, Science, Physics, Solid State Physics
| Author: | Dr Ming-Fa Lin, Dr Szu-Chao Chen, Dr Jhao-Ying Wu, Chiun-Yan Lin | ISBN: | 9780750316743 |
| Publisher: | Institute of Physics Publishing | Publication: | December 11, 2017 |
| Imprint: | Institute of Physics Publishing | Language: | English |
| Author: | Dr Ming-Fa Lin, Dr Szu-Chao Chen, Dr Jhao-Ying Wu, Chiun-Yan Lin |
| ISBN: | 9780750316743 |
| Publisher: | Institute of Physics Publishing |
| Publication: | December 11, 2017 |
| Imprint: | Institute of Physics Publishing |
| Language: | English |
This book addresses important advances in diverse quantization phenomena. Theory of Magnetoelectric Properties of 2D Systems develops the generalized tight-binding model in order to comprehend the rich quantization phenomena in 2D materials. The unusual effects, taken into consideration simultaneously, mainly come from the multi-orbital hybridization, the spin-orbital coupling, the intralayer and interlayer atomic interactions, the layer number, the stacking configuration, the site-energy difference, the magnetic field, and the electric field. The origins of the phenomena are discussed in depth, particularly focusing on graphene, tinene, phosphorene and MoS2, with a broader model also drawn. This model could be further used to investigate electronic properties of 1D and 3D condensed-matter systems, and this book will prove to be a valuable resource to researchers and graduate students working in 2D materials science.
This book addresses important advances in diverse quantization phenomena. Theory of Magnetoelectric Properties of 2D Systems develops the generalized tight-binding model in order to comprehend the rich quantization phenomena in 2D materials. The unusual effects, taken into consideration simultaneously, mainly come from the multi-orbital hybridization, the spin-orbital coupling, the intralayer and interlayer atomic interactions, the layer number, the stacking configuration, the site-energy difference, the magnetic field, and the electric field. The origins of the phenomena are discussed in depth, particularly focusing on graphene, tinene, phosphorene and MoS2, with a broader model also drawn. This model could be further used to investigate electronic properties of 1D and 3D condensed-matter systems, and this book will prove to be a valuable resource to researchers and graduate students working in 2D materials science.
