Lectures
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- Lecture 1: What is nanophysics: Introduction to course topics
- Lecture 2: Survey of quantum statistical tools
- References: Datta Ch. 4
- Lecture 3: From atoms to one-dimensional nanowires
- References: Datta Ch. 5
- Lecture 4: Landauer formula for 1D nanowires
- Lecture 5: Band structure of graphene
- Lecture 6: Introduction to Green functions in quantum physics and application to density of states calculations
- Lecture 7: Introduction to DFT
- References: K. Capelle, A bird's-eye view of density-functional theory, arXiv:cond-mat/0211443
- Lecture 8: Heterojunctions, interfaces and band bending
- Lecture 9: Two-dimensional electron gas in semiconductor heterostructures
- Lecture 10: Split gates shaping of 2DEG and fabrication of quantum nanowires
- Lecture 11: Landauer-Buttiker scattering approach to quantum transport and application to quasi-1D nanowires
- Lecture 12: Graphene nanoribbons
- Lecture 13: Carbon nanotubes
- Lecture 12: Semislassical transport
- References:
- Lecture 13: Drift-diffusion approach to magnetic nanostructure
- Lecture 15: Quantum interference effects in transport: double barrier junction, Aharonov-Bohm ring, localization
- Lecture 16: Quantum Hall effect
- Lecture 17: NEGF for coherent transport
- Lecture 18: NEGF in the presence of dephasing
- Lecture 19: NEGF+DFT and application to molecular electronics
- Lecture 21: Application of NEGF+DFT to magnetic tunnel junctions
- Lecture 22: Coulomb blockade