Quantum Chemistry

Dive into the fundamental principles of quantum chemistry through this comprehensive lecture series. Explore key concepts such as waves and particles, energy exchange between light and matter, and the photoelectric effect. Learn about the time-independent Schrödinger Equation, normalization of state functions, and probability in quantum mechanics. Delve into eigenvalue-eigenfunction equations, orthogonality, and quantum mechanical operators. Examine the relationship between experimental measurements and theoretical calculations, and study wavefunctions and linear combinations of eigenfunctions. Investigate practical applications like the particle in a 1D box model. Progress through advanced topics across 14 lecture sets, each broken down into multiple parts for in-depth understanding of quantum chemical principles and their applications in modern chemistry.

Quantum Chemistry - Lecture 1.1 - [Waves and Particles].
Quantum Chemistry - Lecture 1.2 - [Energy exchange between light and particles].
Quantum Chemistry - Lecture 1.3 - [Photoelectric effect].
Quantum Chemistry - Lecture 1.4 - [The time-independent Schrödinger Equation].
Quantum Chemistry - Lecture 2.1 - [Normalization of the state function].
Quantum Chemistry - Lecture 2.2 - [Probability and the state function; Operators].
Quantum Chemistry - Lecture 2.3 - [Eigenvalue-Eigenfunction Equations; Orthogonality].
Quantum Chemistry - Lecture 2.4 - [Explicit expressions for quantum mechanical operators].
Quantum Chemistry - Lecture 3.1 - [Experimental measurements and theoretical calculations].
Quantum Chemistry - Lecture 3.2 - [Wavefunction & Linear Combination of Eigenfunctions].
Quantum Chemistry - Lecture 3.3.
Quantum Chemistry - Lecture 3.4 - [Particle in a 1D box].
Quantum Chemistry - Lecture 4.1.
Quantum Chemistry - Lecture 4.2.
Quantum Chemistry - Lecture 4.3.
Quantum Chemistry - Lecture 4.4.
Quantum Chemistry - Lecture 5.1.
Quantum Chemistry - Lecture 5.2.
Quantum Chemistry - Lecture 5.3.
Quantum Chemistry - Lecture 5.4.
Quantum Chemistry - Lecture 6.1.
Quantum Chemistry - Lecture 6.2.
Quantum Chemistry - Lecture 6.3.
Quantum Chemistry - Lecture 6.4.
Quantum Chemistry - Lecture 7.1.
Quantum Chemistry - Lecture 7.2.
Quantum Chemistry - Lecture 7.3.
Quantum Chemistry - Lecture 7.4.
Quantum Chemistry - Lecture 8.1.
Quantum Chemistry - Lecture 8.2.
Quantum Chemistry - Lecture 8.3.
Quantum Chemistry - Lecture 8.4.
Quantum Chemistry - Lecture 9.1.
Quantum Chemistry - Lecture 9.2.
Quantum Chemistry - Lecture 9.3.
Quantum Chemistry - Lecture 9.4.
Quantum Chemistry - Lecture 10.1.
Quantum Chemistry - Lecture 10.2.
Quantum Chemistry - Lecture 10.3.
Quantum Chemistry - Lecture 10.4.
Quantum Chemistry - Lecture 11.1.
Quantum Chemistry - Lecture 11.2.
Quantum Chemistry - Lecture 11.3.
Quantum Chemistry - Lecture 11.4.
Quantum Chemistry - Lecture 12.1.
Quantum Chemistry - Lecture 12.2.
Quantum Chemistry - Lecture 12.3.
Quantum Chemistry - Lecture 12.4.
Quantum Chemistry - Lecture 13.1.
Quantum Chemistry - Lecture 14.1.
Quantum Chemistry - Lecture 13.2.
Quantum Chemistry - Lecture 14.2.