Plasmon enhanced Raman scattering effect for an atom near a carbon nanotube

TL;DR

This paper develops a quantum electrodynamics theory predicting significant enhancement of Raman scattering for an atom near a carbon nanotube, enabling advanced optical sensing and emission control.

Contribution

It introduces a theoretical framework for resonance Raman scattering near nanotubes, highlighting the potential for enhanced sensing and emission manipulation.

Findings

Predicted dramatic Raman intensity enhancement in strong coupling regime

Identified surface enhanced Raman scattering as a key mechanism

Potential applications in nanotube-based optical sensors

Abstract

Quantum electrodynamics theory of the resonance Raman scattering is developed for an atom in a close proximity to a carbon nanotube. The theory predicts a dramatic enhancement of the Raman intensity in the strong atomic coupling regime to nanotube plasmon near-fields. This resonance scattering is a manifestation of the general electromagnetic surface enhanced Raman scattering effect, and can be used in designing efficient nanotube based optical sensing substrates for single atom detection, precision spontaneous emission control, and manipulation.