Coherent Quantum Optics Phenomena in Carbon Low-Dimensional Systems

TL;DR

This paper reviews theoretical and experimental advances in quantum field theory applied to low-dimensional carbon systems, highlighting the formation of long-lived coherent states in nanotubes, carbynes, and graphene.

Contribution

It provides a comprehensive overview of how quantum field theory explains coherent phenomena in various low-dimensional carbon materials, emphasizing new insights into their quantum states.

Findings

Identification of long-lived coherent photon-electron states

Experimental evidence supporting quantum coherence in carbon systems

Theoretical models explaining resonance phonon-electron interactions

Abstract

Brief review of the theoretical and experimental results, based mainly on the works of authors, in the application of quantum field theory to the study of carbon low-dimensional systems - quasi-1D carbon nanotubes, carbynes and graphene with emphasis on formation of longlived coherent states of joint photon-electron and joint resonance phonon-electron systems of given materials is presented.