Concept
Fermi energy
Related courses (18)
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Starting from a microscopic description, the course introduces to the physics of quantum fluids focusing on basic concepts like Bose-Einstein condensation, superfluidity, and Fermi liquid theory.
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Ce cours de deux semestres donne une introduction à la Physique du solide, à la structure cristalline, aux vibrations du réseau, aux propriétés électroniques, de transport thermique et électrique ains
PHYS-636: General aspects of the electronic structure of crystals
The course is aimed at giving a general understanding and building a feeling of what electronic states inside a crystal are.
PHYS-434: Physics of photonic semiconductor devices
Series of lectures covering the physics of quantum heterostructures, dielectric microcavities and photonic crystal cavities
as well as the properties of the main light emitting devices that are light-
CH-426: Artificial photosynthesis
This class is intended to make students familiar with dye sensitized solar cells. It presents the principle of design and rationalize the influence of various components on the power conversion effici
MICRO-516: Nanophotonics
Students understand and apply the physics of the interaction of light with semiconductors. They understand the operating mechanism of scaled photonic devices such as photodetectors, LEDs and lasers, a
PHYS-433: Semiconductor physics and light-matter interaction
Lectures on the fundamental aspects of semiconductor physics and the main properties of the p-n junction that is at the heart of devices like LEDs & laser diodes. The last part deals with light-matter
PHYS-312: Nuclear and particle physics II
Introduction générale à la physique des noyaux atomiques: des états liés à la diffusion.
MSE-423: Fundamentals of solid-state materials
Fundamentals of quantum mechanics as applied to atoms, molecules, and solids. Electronic, optical, and magnetic properties of solids.
ME-469: Nano-scale heat transfer
In this course we study heat transfer (and energy conversion) from a microscopic perspective. First we focus on understanding why classical laws (i.e. Fourier Law) are what they are and what are their