Lecture

Evolution of Density Matrices

Related lectures (32)

Covers the evolution of density matrices in quantum optics, focusing on quantum channels and amplitude damping.

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Explores the general description of quantum measurements, including post-measurement states and Kraus operators.

Quantum Physics II: Operator or Density Matrix

Explores operator, density matrix, subsystems, states, and system evolution in quantum physics.

Quantum Entanglement

Explores quantum entanglement, Bell inequalities, and self-testing in quantum systems.

Mach-Zehnder Interferometer

Explores the Mach-Zehnder interferometer, density matrices, and detection probabilities in quantum systems.

Hilbert Space: State, Evolution, Measurement

Introduces Hilbert space as a big place where quantum systems evolve with unitaries.

Theory of Open Quantum Systems

Covers the theory of open quantum systems and the dynamics of isolated systems.

Lindblad equation

Covers the derivation of the Lindblad equation and the evolution of quantum gases.

Noisy Quantum Channels

Explores noisy quantum channels, density operators, probabilities, and time evolution in quantum systems.

Quantum Information: Density Matrices

Explores density matrices, quantum states representation, and entropy in quantum information.

Quantum Mechanics: Time Evolution

Explores time evolution in quantum mechanics, covering compatibility, uncertainty, and evolution properties.

Quantum Principles

Covers the fundamental principles of quantum computing and unitary evolution in quantum systems.

Matrix to Density Operator

Explains the transformation from a matrix to the density operator in quantum physics.

Quantum Entanglement

Delves into quantum entanglement, exploring entangled particles' state, evolution, and measurement.

Quantum Key Distribution

Covers Quantum Key Distribution protocols for generating a common secret using quantum channels and one-time pads.

Density Operator: Quantum Physics II

Covers the concept of matrix to the density operator in quantum physics.

Heisenberg Picture: Time Evolution and Observables

Explores the Heisenberg picture, emphasizing time evolution and observables in quantum mechanics.

Jarzynski Equation and Quantum Circuits

Explores the Jarzynski equation and the quantization of electrical circuits in quantum harmonic oscillators.

Noisy Quantum Channels

Covers noisy quantum channels, depolarizing channels, Kraus operators, and error probabilities in quantum communication.

Quantum Physics I

Introduces key quantum physics concepts such as commutators, observables, and the Schrödinger equation, emphasizing the importance of diagonalization and energy eigenvalues.