Classical and Quantum Mechanics: Foundations and Applications

About
Privacy
Disclaimer

Graph Chatbot

Related lectures (29)

Page 1 of 3

Molecular Structure: Intramolecular Electron Delocalization

Discusses molecular structure and intramolecular electron delocalization, focusing on quantum mechanics and the transition from atomic to molecular orbitals.

Quantum Mechanics: Fundamentals and Applications

Explores quantum mechanics fundamentals, including observables, momentum, Schrödinger equation, hydrogen atom, spin, and quantum information.

Quantum Mechanics: Harmonic Oscillator and Molecular Interactions

Discusses the harmonic oscillator in quantum mechanics and its implications for molecular interactions and energy levels.

Quantum Mechanics: Atomic to Molecular Orbitals

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

Quantum Principles: Atoms and Molecules

Covers the application of quantum principles to the behavior of atoms and molecules, focusing on energy levels and molecular formation.

Quantum Operators: Exponential and Position Measurement

Covers the mathematical foundations of quantum mechanics, focusing on operators and their applications in quantum states.

Quantum Mechanics: Bohr Model and Energy Quantization

Discusses the Bohr model of the atom, focusing on electron orbits and energy quantization.

Quantum to Classical Mechanics: MD & MC Simulations

Covers Molecular Dynamics and Monte Carlo Simulations, transitioning from Quantum to Classical Mechanics in computational chemistry.

Quantum Physics III: Introduction to Relativistic Quantum Mechanics

Introduces relativistic quantum mechanics, Dirac equation, positron prediction, and quantum states properties.

Quantum Mechanics: Composite Systems and Angular Momentum

Explores quantum mechanics concepts applied to composite systems and angular momentum, emphasizing the importance of understanding the basics.