Basic Information
Motivation# When Are Open Quantum Systems Needed. Basic Language# Density Matrix, Tensor States, Reduced States. Model Of The Environment. Environment States. Reduced Dynamics# Lindblad Equation Derivation. What Are The Approximations Used. When Is This Correct. Properties of The Lindblad Equation# Structure of The Equation, Mathematical Properties, Decoupling Between Coherences and Diagonal Elements. How to Solve The Lindblad Equation and Properties of The Steady-state. Example 1 of Applications of Open Quantum Systems. Decoherence Is The Environment The Enemy. Decoherence in Quantum Information and Quantum to Classical Transition Learning Outcomes# at The End of The Course The Students Will Know# - How to Model a Non-isolated Quantum System and to Obtain Bas Intuitions Regarding Its Behavior. -_be Familiar With Basic Modeling of Noise. - How to Write and Solve The Dynamical Equations of a System Under The Influence of Its Surroundings, Starting From a Microscopic Model. - Be Familiar With Basic Modeling of Decoherence.
Faculty: Chemistry
|Graduate Studies
Pre-required courses
114073 - Quantum Physics For Engineering or 115203 - Quantum Physics 1 or 124400 - Quantum Chemistry 1 or 124408 - Intr.to Quantum Chemi.and Applications
Course with no extra credit (contained)
127461 - Introduction to Open Quantum Systems
Semestrial Information
Weekly Hours
2 Academic Credit • 2 Lecture Hours
Responsible(s)
David Andres Gelbwaser
Registration Groups
|
|
|
|
Weekly Hours
2 Academic Credit • 2 Lecture Hours
Responsible(s)
David Andres Gelbwaser
Registration Groups
|
|
|
|