Computational Quantum Mechanics

Learn quantum mechanics through computational methods in this comprehensive video series that bridges theoretical physics with practical programming implementation. Explore fundamental quantum concepts starting with difference equations and the Schrödinger equation, then progress through wave function collapse during measurement and energy eigenstate analysis. Master the construction of wave functions using Fourier methods and develop skills in calculating expectation values for quantum systems. Investigate quantum behavior in potential wells and barriers, tackle unsolved potential energy problems, and compare quantum versus classical probability distributions. Conclude with an in-depth examination of the harmonic oscillator potential, gaining both theoretical understanding and computational expertise essential for modern quantum physics applications.