The book provides an overview of the subject under the effects of lattice symmetries, layer numbers, dimensions, stacking configurations, orbital hybridizations, intralayer and interlayer hopping integrals, spin-orbital couplings, temperatures, electron/hole dopings, electric field, and magnetic quantization.
The book provides an overview of the subject under the effects of lattice symmetries, layer numbers, dimensions, stacking configurations, orbital hybridizations, intralayer and interlayer hopping integrals, spin-orbital couplings, temperatures, electron/hole dopings, electric field, and magnetic quantization.
Chiun-Yan Lin earned a PhD in physics in 2014 at the National Cheng Kung University (NCKU), Taiwan. Since 2014, he has been a postdoctoral researcher in the Department of Physics at NCKU. His scientific interests include the field of condensed matter physics, modeling, and simulation of nanomaterials. Most of his research focuses on the electronic and optical properties of two-dimensional nanomaterials. Jhao-Ying Wu earned a PhD in physics in 2009 at the National Cheng Kung University (Tainan, Taiwan). After that, he was a postdoctoral fellow until 2016. He became a Professor at the National Kaohsiung University of Science and Technology. His interest focuses on theoretical condensed matter physics, including the electronic and optical properties of low-dimensional systems, Coulomb excitations, and quantum transport. Chih-Wei Chiu is an Associate Professor in the Department of Physics, National Kaohsiung Normal University, Taiwan. He earned a PhD in 2005 at the National Cheng Kung University, Taiwan. His research deals with the physical properties of graphene-related nanosystems using numerical simulations. Ming-Fa Lin is a Distinguished Professor in the Department of Physics, National Cheng Kung University, Taiwan. He earned a PhD in physics in 1993 at the National Tsing-Hua University, Taiwan. His scientific interests focus on the essential properties of carbon-related materials and low-dimensional systems.
Inhaltsangabe
1. Introduction 2. Theories for Electronic Excitations in Layered Graphenes, 3D Graphites, and 1D Carbon Nanotubes: Experimental Equipments 3. Monolayer Graphene 4. AA-Stacked Graphenes 5. AB-Stacked Graphenes 6. ABC-Stacked Graphenes 7. AAB-Stacked Graphene 8. Sliding Bilayer Graphene 9. Diversified Effects due to a Perpendicular Electric Field 10. Magnetoelectronic Excitations: Monolayer and Bilayer Graphenes 11. 3D Coulomb Excitations of Simple Hexagonal, Bernal, and Rhombohedral Graphites 12. 1D Electronic Excitations in Metallic and Semiconducting Nanotubes 13. Electronic Excitations in Monolayer Silicene and Germanene 14. Coulomb Decay Rates in Graphene 15. Concluding Remarks and Perspectives 16. Problems
1. Introduction 2. Theories for Electronic Excitations in Layered Graphenes, 3D Graphites, and 1D Carbon Nanotubes: Experimental Equipments 3. Monolayer Graphene 4. AA-Stacked Graphenes 5. AB-Stacked Graphenes 6. ABC-Stacked Graphenes 7. AAB-Stacked Graphene 8. Sliding Bilayer Graphene 9. Diversified Effects due to a Perpendicular Electric Field 10. Magnetoelectronic Excitations: Monolayer and Bilayer Graphenes 11. 3D Coulomb Excitations of Simple Hexagonal, Bernal, and Rhombohedral Graphites 12. 1D Electronic Excitations in Metallic and Semiconducting Nanotubes 13. Electronic Excitations in Monolayer Silicene and Germanene 14. Coulomb Decay Rates in Graphene 15. Concluding Remarks and Perspectives 16. Problems
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