Introduces key quantum physics concepts such as commutators, observables, and the Schrödinger equation, emphasizing the importance of diagonalization and energy eigenvalues.
Explores discrete and continuous degrees of freedom, canonical commutation relations, and the correspondence between classical and quantum mechanics.
Covers the fundamentals of quantum physics, focusing on Hamiltonians, Schrödinger's equation, and magnetic resonance.
Covers time-dependent quantum systems, resonance phenomena, and quantum behavior in molecular ammonia.
Explores the analysis of the Schrödinger equation in realistic scenarios, focusing on angular momentum and the association of physical operations with observables.
Covers the basics of quantum physics, including the Schrödinger equation and Heisenberg's uncertainty principle.
Explores Hamiltonians, Schrodinger equations, composite systems, and quantum measurements in a foundational quantum physics context.
Explores quantum physics, wave-particle duality, and optical phenomena like reflection and interference.
Explores scattering theory, S-matrix, T-product, perturbation theory, and Schrödinger equation solutions.
Covers the fundamentals of quantum physics, including commutation relations and time evolution operators.
Covers the fundamentals of quantum physics, including the Schrödinger equation and bound states.
Explores wave functions, electron density, quantum mechanics principles, operators, Schrödinger's equation, and key quantum terminologies.
