You will only understand the Nano-to-macro transport process if you know the fundamental understanding and descriptive tools for energy and heat transport processes. You will be taught here the different parallel treatments significant to these processes.
This [course_title] will train you on the applications in Nano- and microtechnology. You will be introduced to different transport process topics such as energy levels, statistical behavior, and other types of processes.
This course does not involve any written exams. Students need to answer 5 assignment questions to complete the course, the answers will be in the form of written work in pdf or word. Students can write the answers in their own time. Each answer needs to be 200 words (1 Page). Once the answers are submitted, the tutor will check and assess the work.
Edukite courses are free to study. To successfully complete a course you must submit all the assignment of the course as part of the assessment. Upon successful completion of a course, you can choose to make your achievement formal by obtaining your Certificate at a cost of £49.
Having an Official Edukite Certification is a great way to celebrate and share your success. You can:
- Add the certificate to your CV or resume and brighten up your career
- Show it to prove your success
Course Credit: MIT
|Lecture 1: Intro to Nanotechnology, Nanoscale Transport Phenomena||01:18:00|
|Lecture 2: Characteristic Time and Length, Simple Kinetic Theory||01:20:00|
|Lecture 3: Schrödinger Equation and Material Waves||01:20:00|
|Lecture 4: Solutions to Schrödinger Equation, Energy Quantization||01:22:00|
|Lecture 5: Electronic Levels in One-Dimensional Lattice Chain||01:20:00|
|Lecture 6: Crystal Bonding & Electronic Energy Levels in Crystals||01:20:00|
|Lecture 7: Phonon Energy Levels in Crystal and Crystal Structures||01:22:00|
|Lecture 8: Density of States and Statistical Distributions||01:21:00|
|Lecture 9: Specific Heat and Planck’s Law||01:18:00|
|Lecture 10: Fundamental of Statistical Thermodynamics||01:18:00|
|Lecture 11: Energy Transfer by Waves: Plane Waves||01:21:00|
|Lecture 12: EM Waves: Reflection at a Single Interface||01:21:00|
|Lecture 13: EM Wave Propagation Through Thin Films & Multilayers||01:15:00|
|Lecture 14: Wave Phenomena and Landauer Formalismv||01:21:00|
|Lecture 15: Particle Description, Liouville & Boltzmann Equations||01:19:00|
|Lecture 16: Fermi Golden Rule and Relaxation Time Approximation||01:20:00|
|Lecture 17: Solutions to Boltzmann Equation: Diffusion Laws||01:21:00|
|Lecture 18: Electron Transport and Thermoelectric Effects||01:22:00|
|Lecture 19: Classical Size Effects, Parallel Direction||01:20:00|
|Lecture 20: Classical Size Effects, Perpendicular Direction||01:20:00|
|Lecture 21: Slip Condition, Coupled Energy Transport & Conversion||01:21:00|
|Lecture 22: PN Junction, Diode and Photovoltaic Cells||01:20:00|
|Lecture 23: Liquids: Brownian Motion and Forces in Liquids||01:23:00|
|Lecture 24: Electrical Double Layer, Size Effects in Phase Change||01:17:00|
|Lecture 25: Statistical Foundation for Molecular Dynamics Simulation||01:24:00|
|Submit Your Assignment||00:00:00|
No Reviews found for this course.