Concept
Canonical quantization
Related courses (21)
PHYS-453: Quantum electrodynamics and quantum optics
This course develops the quantum theory of electromagnetic radiation from the principles of quantum electrodynamics. It will cover historic developments (coherent states, squeezed states, quantum theo
PHYS-202: Analytical mechanics (for SPH)
Présentation des méthodes de la mécanique analytique (équations de Lagrange et de Hamilton) et introduction aux notions de modes normaux et de stabilité.
PHYS-431: Quantum field theory I
The goal of the course is to introduce relativistic quantum field theory as the conceptual and mathematical framework describing fundamental interactions.
PHYS-739: Conformal Field theory and Gravity
This course is an introduction to holography, the modern approach to quantum gravity.
PHYS-313: Quantum physics I
The objective of this course is to familiarize the student with the concepts, methods and consequences of quantum physics.
PHYS-207: Quantum mechanics I
The objective of this course is to familiarize the student with the concepts, methods and consequences of quantum physics.
PHYS-454: Quantum optics and quantum information
This lecture describes advanced concepts and applications of quantum optics. It emphasizes the connection with ongoing research, and with the fast growing field of quantum technologies. The topics cov
PHYS-714: Introduction to field theory of driven-dissipative systems
This course introduces modern field-theoretical approaches to non-equilibrium systems. Through practical examples from quantum gases/optics, we construct the Keldysh formalism and explore the connecti
MICRO-410: Classical and quantum photonic transducers
This course gives an introduction to transducers by both considering fundamental principles and their application in classical and quantum systems. The course builds up on the fundamental concept of c
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