3: Solving the Time-Dependent Schrödinger Equation

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3.1: Introduction
Many types of problems exist in quantum dynamics, and the number of ways of solving them is equally diverse. Most importantly, analytical or exact methods almost never exist.
3.2: Integrating the TDSE Directly
An overview of how one approaches a direct integration of the time-dependent Schrödinger equation with discrete time-steps, and the challenges to this approach.
3.3: Transitions Induced by a Time-Dependent Potential
The general approach to solving problems when a well defined molecular system is acted on by an external potential.
3.4: Resonant Driving of a Two-Level System
The dynamics of a two-level system when it is driven by a sinusoidally oscillating external potential. This is a first look at a model for a molecular system interacting with an electromagnetic field.
3.5: The Interaction Picture
The interaction picture, a hybrid of the Schrödinger and Heisenberg representations, leads to a practical way of solving the time-dependence of a system subject to an external potential.
3.6: Time-Dependent Perturbation Theory
Time-dependent perturbation theory is the most widely used tool in quantum dynamics. We show how it emerges from the interaction picture, and investigate an example of first-order perturbation theory.
3.7: The Golden Rule
The Golden Rule of perturbation theory, commonly attributed to Fermi but originally from Dirac, describes the rate of transitions between two quantum states. We derive Golden Rule expressions for the case of a constant perturbation and a sinusoidal perturbation.

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