Lectures related to Perturbations: Independent Time Perturbations

Principles of Quantum Mechanics: Wave-Particle Dualism

Explores the wave-particle dualism in quantum mechanics and the quantification of energy levels in atoms.

Explores quantum mechanics, emphasizing the harmonic oscillator and particle confinement in a box.

Explores the classical and quantum-mechanical basis of nuclear magnetization and the quantization of angular momentum and energy levels.

Quantum Mechanics: Bound-State Problems

Analyzes bound-state problems, Bohr-Sommerfeld quantization, and tunneling through potential barriers in quantum mechanics.

Advanced General Chemistry I

Explores the quantization of energy levels, wave-particle duality, and uncertainty principle in advanced general chemistry.

Energy Levels in Quantum Mechanics

Explains energy levels in quantum mechanics, including calculations with Planck's constant and electron charge.

Statistical Thermodynamics: Density of States

Explores density of states in statistical thermodynamics and the use of Heaviside functions for energy level probabilities.

Quantum Wells: Understanding Potential and Wave Functions

Discusses quantum wells, potential steps, tunneling effects, and their applications in quantum mechanics and electronic devices.

Independent Time Perturbations

Explores independent time perturbations in quantum mechanics and the Brillouin-Wigner method.

Quantum Chemistry: Fundamentals of Quantum Mechanics

Covers the fundamentals of quantum mechanics and the behavior of particles at the quantum level.

Time-Independent Perturbations 2

Explores time-independent perturbations in quantum mechanics and their effects on energy levels and eigenstates.

Quantum Physics: Wave Nature and Measurement Interpretation

Explores wave nature, Schrödinger's equation solutions, and quantum measurement 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 Mechanics: Postulates and Observables

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

Time-Independent Perturbation Theory: Degenerate Case

Explores time-independent perturbation theory in the degenerate case within quantum physics.

Quantum Mechanics: Atomic Spectra

Explores quantum mechanics principles, focusing on atomic spectra and the failures of classical mechanics to explain them.

Eigenstates in Non-Infinite Well Potential

Focuses on finding an eigenstate of energy E0 in a non-infinite well potential by considering the Schrodinger equation.

Quantum Mechanics: Particle in a Box

Covers the quantum mechanics of a particle in a confined box and its energy levels.

The Particle in a Box

Covers the particle in a box, discussing wave functions and energy levels.

Quantum Well: Zero Point Energy Calculation

Explains how to calculate the zero point energy of a particle in a quantum well.