Lectures related to Quantum Trajectories: Stochastic Schrödinger Equation

Quantum Trajectories: Lindblad Equation and Measurements

Covers the stochastic Schrödinger equation, Lindblad equation, and continuous measurements in quantum optics.

Quantum Trajectories: Stochastic Schrödinger Equation

Covers the Stochastic Schrödinger equation, Lindblad equation, and Homodyning.

Quantum Physics: Interpretations and Dynamics

Explores quantum physics concepts, dynamics, interpretations, and implications on classical mechanics.

Quantum Physics: Wave Nature and Measurement Interpretation

Explores wave nature, Schrödinger's equation solutions, and quantum measurement interpretation.

Path Integral Evolution Operator

Covers the path integral evolution operator representation and the semiclassical approximation in quantum mechanics.

Matrix to Density Operator

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

Quantum Mechanics: Atomic to Molecular Orbitals

Explores quantum mechanics from atomic to molecular orbitals, covering the Schrödinger equation, quantum numbers, and wavefunction interpretation.

Classical and Quantum Mechanics: Foundations and Applications

Explores classical and quantum mechanics, covering observables, momentum, Hamiltonian, and the Schrödinger equation, as well as quantum chemistry and the Schrödinger's cat experiment.

Quantum Chemistry

Covers eigenvalues, eigenfunctions, Hermitian operators, and the measurement of observables in quantum chemistry.

Density Operator: Matrix to the System State

Explores density operator matrix transformation in quantum physics and the implications of measuring the system, leading to state collapse.

Quantum Mechanics: Schrödinger Equation

Explores the Schrödinger equation in quantum mechanics, emphasizing conservation of probability and numerical schemes.

Mach-Zehnder Interferometer

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

Separation of Variables

Explores the concept of separation of variables in quantum mechanics and its application in solving differential equations.

Quantum Physics II: Operator or Density Matrix

Explores operator or matrix density in quantum physics, discussing system evolution and interactions with the environment.

Computational Quantum Physics

Covers the ground-state quantum Monte Carlo method and its statistical interpretation.

Quantum Chemistry: Eigenfunctions and Operators

Explores eigenfunctions and operators in quantum chemistry, emphasizing their significance in understanding bound states.

Quantum Physics IV: Path Integral

Covers the concept of path integral in quantum physics, focusing on phase space path integral and real space path integral.

Quantum Mechanics: Postulates and Observables

Explains the postulates of quantum mechanics and the representation of observables by operators.

Density Operator: Quantum Physics II

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

Symmetry Operations in Quantum Mechanics

Explores symmetry operations in quantum mechanics, emphasizing the preservation of state properties.