Coursera
How Things Work: An Introduction to Physics - University of Virginia
Fundamentals of waves and vibrations - Ecole Polytechnique
Introduction to Basic Vibrations - KAIST
Introduction to Advanced Vibrations - KAIST
Intro to Acoustics (Part 1) - KAIST
Introduction to Acoustics (Part 2) - KAIST
Fundamentals of Audio and Music Engineering: Part 1 Musical Sound & Electronics - University of Rochester
Audio Signal Processing for Music Applications - Universitat Pompeu Fabra of Barcelona
Sound and Sonification Design for Interactive Learning Tools - Georgia Institute of Technology
Fundamentals of Digital Image and Video Processing - Northwestern University
Image and Video Processing: From Mars to Hollywood with a Stop at the Hospital - Duke University
Advanced Machine Learning and Signal Processing - IBM
Computers, Waves, Simulations: A Practical Introduction to Numerical Methods using Python - LMU
Digital Systems: From Logic Gates to Processors - Universitat Autònoma de Barcelona
Digital Signal Processing 1: Basic Concepts and Algorithms - EPFL
Digital Signal Processing 2: Filtering - EPFL
Digital Signal Processing 3: Analog vs Digital - EPFL
Digital Signal Processing 4: Applications - EPFL
Fundamentals of Network Communication - University of Colorado
Peer-to-Peer Protocols and Local Area Networks - University of Colorado
Packet Switching Networks and Algorithms - University of Colorado
TCP/IP and Advanced Topics - University of Colorado
Introduction to TCP/IP - Yonsei University
Wireless Communications for Everybody - Yonsei University
Introduction to Satellite Communications - Institut Mines-Télécom
Introduction to Thermodynamics: Transferring Energy from Here to There - University of Michigan
Electrodynamics: An Introduction - KAIST
Exploring Quantum Physics - University of Maryland
Particle Physics: an Introduction - University of Geneva
Fundamentals of Macroscopic and Microscopic Thermodynamics - University of Colorado
Quantum Mechanics - University of Colorado
Ideal Gases - University of Colorado
Dense Gases, Liquids and Solids - University of Colorado
Non-Equilibrium Applications of Statistical Thermodynamics - University of Colorado
EdX
Vibrations and Waves - MIT
Waves & Optics - Rice University
Introductory Physics — Part 1: Mechanics and Waves - Seoul National University
Dynamics - MIT
Mechanics: Kinematics and Dynamics - MIT
Mechanics: Momentum and Energy - MIT
Mechanics: Rotational Dynamics - MIT
Mechanics: Simple Harmonic Motion - MIT
Electricity and Magnetism: Electrostatics - MIT
Electricity and Magnetism: Magnetic Fields and Forces - MIT
Electricity and Magnetism: Maxwell’s Equations - MIT
Electricity and Magnetism, Part 1 - Rice University
Electricity & Magnetism, Part 2 - Rice University
Electricity and Magnetism: Electrostatics - MIT
Electricity and Magnetism: Magnetic Fields and Forces - MIT
Electricity and Magnetism: Maxwell’s Equations - MIT
Mechanics ReView - MIT
Mechanics, Part 1 - Rice University
Mechanics, Part 2 - Rice University
Question Everything: Scientific Thinking in Real Life - University of Queensland
Engineering Mechanics - Ural Federal University
Science & Cooking: From Haute Cuisine to Soft Matter Science (physics) - Harvard University
Backyard Meteorology: The Science of Weather - Harvard Unviersity
Introduction to Aerospace Structures and Materials - TU Delft
Preparing for the AP Physics 1 Exam - Boston University
Preparing for the AP* Physics C: Electricity and Magnetism Exam - Georgetown University
On-Ramp to AP* Physics C: Mechanics - Weston High School
AP® Physics 1: Challenging Concepts - Davidson College
AP® Physics 2: Challenging Concepts - Davidson College
AP Physics 1 - Rice Unviersity
AP® Physics 1 - Part 1: Linear Motion - Rice University
AP® Physics 1 - Part 2: Rotational Motion - Rice University
AP® Physics 1 - Part 4: Exam Prep - Rice University
AP® Physics 2 - Part 1: Fluids and Thermodynamics - Rice Unviersity
AP® Physics 2 - Part 2: Electricity and Magnetism - Rice Unviersity
AP® Physics 2 - Part 3: Optics and Modern Physics - Rice Unviersity
AP® Physics 2 – Part 4: AP Review and Exam Preparation - Rice Unviersity
Semiconductor Fundamentals - Purdue University
Nanophotonic Modeling - Purdue University
Fundamentals of Current Flow - Purdue University
Fundamentals of Transistors - Purdue University
Nanotechnology: Fundamentals of Nanotransistors - MIT
Fiber Optic Communications - Purdue University
Introduction to Quantum Transport - Purdue University
Solid State Devices 1 - Purdue University
Advanced Fluid Mechanics: Fundamentals - MIT
Complex Analysis - MISIS
Complex Analysis with Physical Applications - MISIS
Introduction to the Modern Nanotechnology - National Research Nuclear University
Symmetry, Structure and Tensor Properties of Materials - MIT
Thermodynamics of Materials - MIT
Thermodynamics - IIT Bombay
Introduction to Computational Materials Design - Osaka University
Materials Science and Engineering - MISIS
The Basics of Transport Phenomena - TU Delft
Advanced Transport Phenomena - TU Delft
Analysis of Transport Phenomena I: Mathematical Methods - MIT
Analysis of Transport Phenomena II: Applications - MIT
Quantum Mechanics for Everyone - Georgetown University
The Einstein Revolution - Harvard University
Quantum Mechanics and Quantum Computation - UC Berkeley
Quantum Mechanics of Molecular Structures - University of Tokyo
Quantum Mechanics: A First Course - MIT
Applications of Quantum Mechanics - MIT
Quantum Mechanics: Wavefunctions, Operators, and Expectation Values - MIT
Quantum Mechanics: Quantum physics in 1D Potentials - MIT
Quantum Mechanics: 1D Scattering and Central Potentials - MIT
Atomic and Optical Physics: Quantum States and Dynamics of Photons - MIT
Atomic and Optical Physics: Atom-photon interactions - MIT
Atomic and Optical Physics: Optical Bloch Equations and Open System Dynamics - MIT
Atomic and Optical Physics: Light Forces and Laser Cooling - MIT
Atomic and Optical Physics: Ultracold Atoms and Many-body Physics - MIT
Atomic and Optical Physics I– Part 1: Resonance - MIT
Atomic and Optical Physics I – Part 2: Atomic structure and atoms in external field - MIT
Atomic and Optical Physics I– Part 3: Atom-Light Interactions 1 -- Matrix elements and quantized field - MIT
Atomic and Optical Physics I– Part 4: Atom-Light Interactions 2: Line Broadening and Two-Photon Transitions - MIT
Atomic and Optical Physics I – Part 5: Coherence - MIT
Effective Field Theory - MIT
Mastering Quantum Mechanics Part 1: Wave Mechanics - MIT
Mastering Quantum Mechanics Part 2: Quantum Dynamics - MIT
Mastering Quantum Mechanics Part 3: Entanglement and Angular Momentum - MIT
The Hardware of a Quantum Computer - TU Delft
Graphene Science and Technology - Chalmers University of Technology
Architecture, Algorithms, and Protocols of a Quantum Computer and Quantum Internet - TU Delft
The Quantum Internet and Quantum Computers: How Will They Change the World? - TU Delft
Topology in Condensed Matter: Tying Quantum Knots - TU Delft
Introduction to Quantum Science & Technology - Purdue University
Quantum Networking - Purdue University
Quantum Detectors and Sensors - Purdue University
Applied Quantum Computing I: Fundamentals - Purdue University
Applied Quantum Computing II: Hardware - Purdue University
Quantum Information Science I, Part 3 - MIT
Quantum Information Science II: Efficient Quantum Computing - fault tolerance and complexity - MIT
Quantum Information Science II: Advanced quantum algorithms and information theory - MIT
Quantum Information Science II: Quantum states, noise and error correction - MIT
Quantum Cryptography - Caltech
Synthetic Aperture Radar: Hazards - University of Alaska
Understanding Nuclear Energy - TU Delft
Nuclear Facilities: Regulations and Licensing - National Research Nuclear University
Basic Concepts of International Nuclear Law - National Research Nuclear University
Introduction to the Theory of Ferromagnetism - National Research Nuclear University
Remote Sensing of Wildfires - University of Alaska
Plasmonics: From Fundamentals to Modern Applications - ITMO University
Plasma Physics: Introduction - EPFL
Plasma Physics: Applications - EPFL
Stochastic Processes: Data Analysis and Computer Simulation - Kyoto University
Surface Science: Methods of Surface Analysis - National Research Nuclear University
Fundamentals of Biomedical Imaging: Magnetic Resonance Imaging (MRI) - EPFL
Fundamentals of Biomedical Imaging: Ultrasounds, X-ray, positron emission tomography (PET) and applications - EPFL
Synchrotrons and X-Ray Free Electron Lasers - EPFL
Physics of COVID-19 Transmission - MIT
Principle of Semiconductor Devices Part II: Field Effect Transistors and MOSFETs - Hong Kong University of Science and Technology
Modeling and simulation of multibody systems - UC Louvain
How Stuff Moves, Part 1: Linear Motion - Harvey Mudd College
How Stuff Moves, Part 2: Angular Motion - Harvey Mudd College
How Stuff Moves, Part 3: Wave Motion - Harvey Mudd College
Solar Energy - TU Delft
Solar Energy: Photovoltaic (PV) Energy Conversion - TU Delft
Solar Energy: Photovoltaic (PV) Technologies - TU Delft
Solar Energy: Photovoltaic (PV) Systems - TU Delft
Solar Energy: Integration of Photovoltaic Systems in Microgrids - TU Delft
Solar Energy Engineering: Comprehensive Exams - TU Delft
Sustainable Energy: Design a Renewable Future - TU Delft
Modeling Climate Change - University of Chicago
Global Warming Science - MIT
Introduction to Aerospace Structures and Materials - TU Delft
Hypersonics – from Shock Waves to Scramjets - University of Queensland
Hyperloop: Changing the Future of Transportation - TU Delft