ECE 495N: Fundamentals of Nanoelectronics Lecture Notes (Fall 2009)
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- Lecture Notes (Fall 2009) Download
- Lecture 1: What Makes Current Flow?
- Lecture 2: Quantum Conductance
- Lecture 3: Current
- Lecture 4: Charging Effect
- Lecture 5: I-V Characteristics I
- Lecture 6: I-V Characteristics II
- Lecture 7: Schrödinger Equation - Basic Concepts
- Lecture 8: Schrödinger Equation - Finite Difference Method
- Lecture 9: Schrödinger Equation: Separation of Variables
- Lecture 10: Atomic Energy Levels
- Lecture 11: Charging Energy
- Lecture 12: Single vs. Multi Electron Picture I
- Lecture 13: Single vs. Multi Electron Picture II
- Lecture 14: Law of Equilibrium
- Lecture 15: Covalent Bonding
- Lecture 16: Bonding
- Lecture 17: Basis Function I
- Lecture 18: Basis Function II
- Lecture 19: Bandstructure I
- Lecture 20: Bandstructure II
- Lecture 21: Graphene Bandstructure
- Lecture 22: Density of States I
- Lecture 23: Density of States II
- Lecture 24: Graphene Density of States
- Lecture 25: Modes
- Lecture 26: Reciprocal Lattice
- Lecture 27: Quantum Dot, wire and well
- Lecture 28: Ballistic Regime Conductance
- Lecture 29: Resistivity
- Lecture 30: Transmission Coefficient
- Lecture 31: Non-Equilibrium Green's Function (NEGF) Method
- Lecture 32: NEGF I
- Lecture 33: NEGF II
- Lecture 34: Transmission
- Lecture 35: Non-coherent Transport
- Lecture 36: Spin Valve
- Lecture 37: Pauli Spine Matrices I
- Lecture 38: Pauli Spine Matrices II
- Lecture 39: Pauli Spine Matrices III
- Lecture 40: Exchange Field
- Lecture 41: Thermoelectricity I
- Lecture 42: Thermoelectricity II