2. Instructor Information
3. Course Objectives
This lecture focuses on basic understanding of the topological properties of materials and discusses the applications of information devices and topological quantum computers based on topological materials. To achieve this, we first study basic quantum mechanics and methods for calculating the band structure of materials, and discuss the topological properties of wave functions. Next, we study about the topological properties of two-dimensional semiconductor materials and graphene, and understand the theoretical descriptions of topological systems such as topological insulators, topological superconductors, and the quantum Hall effect. Based on this knowledge, we further explore the recent device applications through reviewing information devices based on the topological quantum materials, and the implementation of topological quantum computers.
4. Prerequisites & require
Basic knowledge of quantum mechanics, Basic knowledge of Condensed matter physics or physical electronics
: Quantum Mechanics, Physics of Materials, Physical Electronics, Quantum Chemistry, or any equivalents.
5. Grading
Attendance(5%), Homework(60%), Final Report (35%)
6. Course Materials
| Title |
Author |
Publisher |
Publication
Year/Edition |
ISBN |
|
Lecture Note
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|
0000
|
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Topological Insulators (S.Q. Shen)
|
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|
0000
|
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Quantum Hall Effects (Z.F. Ezawa)
|
|
|
0000
|
|
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Topological Insulators and Topological Superconductors (B.A. Bernevig)
|
|
|
0000
|
|
8. Course Plan
Week 1~3 : Basic quantum mechanics in a solid
- Introduction to Quantum Mechanics, Schrodinger Equation
- Aharanov-Bohm Effect, Adiabatic Theorem
- Berry Phase, Berry Curvature, Topological Invariants
- Schrodinger Equation in a solid
- Band Theory and Tight binding method – Graphene, 2D Semiconductors
Week 4~7 : Topological Systems I
- 1D Topological systems : SSH Model
- Berry phase description of Electric Polarization, Ferroelectricity
- 2D Topological system I : Quantum Hall Effect, Adiabatic Charge Pumping
- 2D Topological system II : Quantum Anomalous Hall Effect (Haldane model, QWZ model), Bulk-boundary correspondence
- 2D Topological system III : Quantum Spin Hall Insulator (Kane-Mele Model, BHZ model)
Week 9 ~10: Topological Systems II
- 3D Topological Insulator
- Topological Semimetals
- Fractional Quantum Hall system
- Topological Superconductors
- Topological Flat band systems
Week 11~13: Topological Quantum Computation
- Anyon models and braiding anyons
- Quantum Gates – Braiding Anyons
- Quantum Measurement – Fusing Anyons
- Majorana zero mode in a superconducting nanowire
- Manipulating and Reading out Majorana qubits
Week 14~15: Topological Devices Applications
- Topological optoelectronic devices
- Topological field-effect transistors, Topological PN Junctions
- Topological Magnetic Devices (SOT-based topological device, Magneto-electric effect-based topological device
9. Course Operation
Offline class 100%
10. How to Teach & Remark
11. Supports for Students with a Disability
- Taking Course: interpreting services (for hearing impairment), Mobility and preferential seating assistances (for developmental disability), Note taking(for all kinds of disabilities) and etc.
- Taking Exam: Extended exam period (for all kinds of disabilities, if needed), Magnified exam papers (for sight disability), and etc.
- Please contact Center for Students with Disabilities (279-2434) for additional assistance