Physics 571, Condensed Matter Physics (I), Fall 2022, 2021,2023
Physics 571, Condensed Matter Physics (I), Fall 2023
This covers the basic concept and some theorical tools in condensed matter physics including understand the transport, magnetization, superconducting properties, and field theory methods, gauge theories, and topological concepts in many-body electronic systems.
Physics 571, Condensed Matter Physics (I), Fall 2022
This course covers the basic concept and some theorical tools in condensed matter physics including understand the transport, magnetization, superconducting properties, and field theory methods, gauge theories, and topological concepts in many-body electronic systems.
Students Term Paper
Hao-Ru Wu: Twisted Bilayer Graphene (TBG) and Superconductivity
Yuan-Je Yang: Theory of Type II Superconductor
Le Quang Nhat: no title
Jang-Hung Yu: Introduction of 2D Anisotropic Dirac Cone
Wei-Shen Chen: Introducing The Applications of Superconductor in Quantum Computer
Hsueh-Hao Lu: Size Effect of Solute Atom in Grain Boundary Region
Hsuan-Ning Chen: Axion insulator
Chen-Chih Wang: Chiral Twisted Graphene Multilayers and its Topological Properties
Chia-Hao Wei: Quantum Spin Hall Effect
Hung-Chin Lee: Rewriting of "Topological insulators from the perspective of first-principles calculations"
Pei-Tze Chen: Experimental realization of quantum anomalous Hall effect
Jean Nelson: Analog Black Holes and Energy Extraction by Super-Radiance from Bose Einstein Condensates (BEC) with Constant Density
Yu-Ching Wong: 4 Dimensional Spinless Topological Insulator
Ruei-Syuan Chiang: Effects of Single Defect Position on the Characteristics of Ginzburg-Landau Free Energy and Potential Differences of Type II Superconductor
Assad Alejandro Climent Tame: Majorana Fermions and the Bulk-Edge Correspondence in the Kitaev Chain Model
Ching-Yueh Huang: Tight-binding model study of interaction strength in graphene systems
Chuan-Fu Lin: Introduction to Bethe Ansatz in Condensed Matter Physics
You-Ying Ji: Single magnetic adsorbates on s-wave superconductors
Tao-Lin Tan: Partial thermalisation of a two-state system coupled to a finite quantum bath
Heng-Hsi Li: (2 + 1)d time-reversal breaking insulator
Physics 571, Condensed Matter Physics (I), Fall 2021
This course covers the basic concept and some theorical tools in condensed matter physics including understand the transport, magnetization, superconducting properties, and field theory methods, gauge theories, and topological concepts in many-body electronic systems.
Students Term PaperChih-Chun Wang: Floquet Time Crystal
Chen-En Yin: Spin Chern number and its properties in two-dimensional material
詹承諭: Introduction of VASP and spin-related energy band gap of half-metal CrO2
Daniel Yang: Power-law Temperature dependence of the Penetration Depth in a Superconductor due to surface states
Hung-Hsun Wang: Solving quantum many-body system by Exact Diagonalization and Tensor network
Heng-Wei Chang: A Note on Symmetries and their Breaking
Qian-Can Chen: Review of Quantum Hall Effect
Chun-I Wu: 銅氧化物超導體之電子激發及共振非彈性軟 X 光散射
Jin-Ming Hu: Room-Temperature Superconductivity in a Carbonaceous Sulfur Hydride
Jun-Yan Jiang: Superconductor
Jian-Yi Liao: Majorana Fermions In Spinless Topological Superconductor
Mei-Ian Sam: Theoretical study to the Anderson localizaton and metal-insulator transition
Peng-Chun Wang: High-temperature topological superconductivity in twisted double-layer copper oxidesPo-Wei Huang: Josephson Parametric amplifierLe Quang Nhat: Graphene nanoribbons
Shih-Hsuan Lin: Introduction to time crystal
Tien-Fu Yang: Introduction to Photonic Crystals
Teng-Jen Shih: Meanfield solution for magnetic phase diagram
Ting-Yu Chen: A comprehensive study of germanium growth on Au(111)
Yu-Shin Huang: Josephson effect
Yu-Tzu Chang: Novel Superconducting Phases of Cooper Pairs Carrying Nonzero Central Mass Momentum