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MIT OpenCourseWare

MIT 2.57 Nano-to-Micro Transport Processes, Spring 2012

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25 items
Last updated on Jun 23, 2014
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Instructor: Prof. Gang Chen
View the complete course: http://ocw.mit.edu/2-57S12

This course aims at a fundamental understanding of descriptive tools for energy and heat transport processes, from nanoscale to macroscale. Student will further learn the applications in nanotechnology and microtechnology.

License: Creative Commons BY-NC-SA
More information at http://ocw.mit.edu/terms
More courses at http://ocw.mit.edu
MIT OpenCourseWare
1. Intro to Nanotechnology, Nanoscale Transport Phenomena
1:18:11
1. Intro to Nanotechnology, Nanoscale Transport Phenomena

MIT OpenCourseWare
2. Characteristic Time and Length, Simple Kinetic Theory
1:20:35
2. Characteristic Time and Length, Simple Kinetic Theory

MIT OpenCourseWare
3. Schrödinger Equation and Material Waves
1:20:35
3. Schrödinger Equation and Material Waves

MIT OpenCourseWare
4. Solutions to Schrödinger Equation, Energy Quantization
1:22:12
4. Solutions to Schrödinger Equation, Energy Quantization

MIT OpenCourseWare
5. Electronic Levels in One-Dimensional Lattice Chain
1:20:06
5. Electronic Levels in One-Dimensional Lattice Chain

MIT OpenCourseWare
6. Crystal Bonding & Electronic Energy Levels in Crystals
1:20:18
6. Crystal Bonding & Electronic Energy Levels in Crystals

MIT OpenCourseWare
7. Phonon Energy Levels in Crystal and Crystal Structures
1:22:02
7. Phonon Energy Levels in Crystal and Crystal Structures

MIT OpenCourseWare
8. Density of States and Statistical Distributions
1:21:20
8. Density of States and Statistical Distributions

MIT OpenCourseWare
9. Specific Heat and Planck's Law
1:18:41
9. Specific Heat and Planck's Law

MIT OpenCourseWare
10. Fundamental of Statistical Thermodynamics
1:18:20
10. Fundamental of Statistical Thermodynamics

MIT OpenCourseWare
11. Energy Transfer by Waves: Plane Waves
1:21:34
11. Energy Transfer by Waves: Plane Waves

MIT OpenCourseWare
12. EM Waves: Reflection at a Single Interface
1:21:28
12. EM Waves: Reflection at a Single Interface

MIT OpenCourseWare
13. EM Wave Propagation Through Thin Films & Multilayers
1:15:24
13. EM Wave Propagation Through Thin Films & Multilayers

MIT OpenCourseWare
14. Wave Phenomena and Landauer Formalism
1:21:32
14. Wave Phenomena and Landauer Formalism

MIT OpenCourseWare
15. Particle Description, Liouville & Boltzmann Equations
1:19:20
15. Particle Description, Liouville & Boltzmann Equations

MIT OpenCourseWare
16. Fermi Golden Rule and Relaxation Time Approximation
1:20:51
16. Fermi Golden Rule and Relaxation Time Approximation

MIT OpenCourseWare
17. Solutions to Boltzmann Equation: Diffusion Laws
1:21:58
17. Solutions to Boltzmann Equation: Diffusion Laws

MIT OpenCourseWare
18. Electron Transport and Thermoelectric Effects
1:22:25
18. Electron Transport and Thermoelectric Effects

MIT OpenCourseWare
19. Classical Size Effects, Parallel Direction
1:20:33
19. Classical Size Effects, Parallel Direction

MIT OpenCourseWare
20. Classical Size Effects, Perpendicular Direction
1:20:03
20. Classical Size Effects, Perpendicular Direction

MIT OpenCourseWare
21. Slip Condition, Coupled Energy Transport & Conversion
1:21:02
21. Slip Condition, Coupled Energy Transport & Conversion

MIT OpenCourseWare
22. PN Junction, Diode and Photovoltaic Cells
1:20:41
22. PN Junction, Diode and Photovoltaic Cells

MIT OpenCourseWare
23. Liquids: Brownian Motion and Forces in Liquids
1:23:27
23. Liquids: Brownian Motion and Forces in Liquids

MIT OpenCourseWare
24. Electrical Double Layer, Size Effects in Phase Change
1:17:38
24. Electrical Double Layer, Size Effects in Phase Change

MIT OpenCourseWare
25. Statistical Foundation for Molecular Dynamics Simulation
1:24:06
25. Statistical Foundation for Molecular Dynamics Simulation