Light-Matter Interactions: A Coupled Oscillator Description

TL;DR

This paper presents a classical coupled oscillator model that accurately mimics quantum light-matter interactions, including phenomena like Rabi oscillations, providing a new perspective on quantum systems through classical analogues.

Contribution

It introduces a classical harmonic oscillator framework to model quantum two-level systems, deriving Bloch equations and analogues of quantum phenomena.

Findings

Classical oscillators can replicate quantum two-level system behavior.

The model reproduces Rabi oscillations and coherent control effects.

Derivation of Bloch equations from a classical perspective.

Abstract

The semiclassical theory of light-matter interactions describes the interaction between a classical electromagnetic field with a quantum mechanical two-level system.We show that the quantum mechanical two-level system can be modeled by a system of two coupled classical harmonic oscillators whose eigenstates are split in frequency according to the coupling strength and play the roles of the two levels of the quantum mechanical two-level system. The effect of the light field on the mechanical system is modeled as a modulation of the spring constants of the individual oscillators. Using this fully classical model, we derive the Bloch equations for a two-level system and discuss the mechanical analogues of Rabi oscillations and coherent control experiments