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Electronic, optical and magnetic properties of materials originate from their electronic and molecular structure and the process of this origination is described in this [course_title] appropriately for you. This [course_title] is needed for you to design particular applications like optical fibers, magnetic data storage, solar cells, transistors etc. With vivid real-life examples, applications and EOM property measurements, this [course_title] will help you learn Hamiltonian Mechanics, Phonons, Magnetic Domains, Maxwell’s-Equations etc.
Assessment
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.
Certification
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Course Credit: MIT
Course Curriculum
Introduction and course overview | 00:15:00 | ||
The Hamiltonian approach to classical mechanics Analysis of a simple oscillator | 00:10:00 | ||
The Hamiltonian approach to classical mechanics Analysis of vibrations in one-dimensional lattice | 00:10:00 | ||
The Hamiltonian analysis of lattice vibrations Phononic bandgap | 00:10:00 | ||
Introduction to quantum mechanical way of thinking | 00:10:00 | ||
Quantum mechanical systems and measurements Observables | 00:15:00 | ||
Quantum mechanical systems and measurements Spectral decomposition | 00:10:00 | ||
Quantum mechanical measurements Symmetries, conserved quantities, and the labeling of states | 00:10:00 | ||
Symmetries, conserved quantities, and the labeling of states Angular momentum | 00:10:00 | ||
The hydrogen atom | 00:10:00 | ||
Waves in periodic potentials Part I | 00:05:00 | ||
Waves in periodic potentials Part II | 00:10:00 | ||
Band gap | 00:15:00 | ||
Band diagrams | 00:10:00 | ||
The free electron gas Density of states | 00:10:00 | ||
Fermi-Dirac distribution | 00:10:00 | ||
Carriers in intrinsic semiconductors | 00:10:00 | ||
Engineering conductivity through doping | 00:10:00 | ||
The P-N junction (the diode) | 00:20:00 | ||
Light emitting diodes | 00:10:00 | ||
Reminder introduction to wave optics | 00:15:00 | ||
Electromagnetic waves@s | 00:10:00 | ||
Layered materials and photonic band diagrams | 00:10:00 | ||
Origins of magnetization | 00:10:00 | ||
Hysteresis in ferromagnetic materials | 00:10:00 | ||
Magnetic domains | 00:10:00 | ||
Course summary and review for final exam | 00:20:00 | ||
Assessment | |||
Submit Your Assignment | 00:00:00 | ||
Certification | 00:00:00 |
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