Electro-Optic Effect Explanation with Quantum Photonic Model

TL;DR

This paper explains the transverse electro-optic effect using a quantum-photonic model, simulating photon-electron interactions and waveguide responses to electric fields and different wavelengths.

Contribution

It introduces a quantum-photonic model to interpret the electro-optic effect and employs Monte-Carlo simulations for dynamic analysis.

Findings

Waveguide response varies with applied electric field and wavelength

Photon-electron interactions are key to the electro-optic effect

Monte-Carlo simulation effectively models the effect in time domain

Abstract

In this paper, we have explained transverse electro-optic effect by quantum-photonic model (QPM). This model interpret this effect by photon-electron interaction in attosecond regime. We simulate applied electric field on molecule and crystal by Monte-Carlo method in time domain when a light beam is propagated through the waveguide. We show how the waveguide response to an optical signal with different wavelengths when a transverse electric field applied to the waveguide.