Litcius/Paper detail

Tuning and Enhancing Quantum Coherence Time Scales in Molecules via Light-Matter Hybridization

Wenxiang Hu, Ignacio Gustín, Todd D. Krauss, Ignacio Franco

2022The Journal of Physical Chemistry Letters27 citationsDOIOpen Access PDF

Abstract

coherence time scales that are longer than those of the bare molecule, even at room temperature and for molecules immersed in solvent. For this, we develop a theory of decoherence rates for molecular polaritonic states and demonstrate that quantum superpositions that involve such hybrid light-matter states can survive for times that are orders of magnitude longer than those of the bare molecule while remaining optically controllable. Further, by studying these tunable coherence enhancements in the presence of lossy cavities, we demonstrate that they can be enacted using present-day optical cavities. The analysis offers a viable strategy to engineer and increase quantum coherence lifetimes in molecules.

Topics & Concepts

Coherence (philosophical gambling strategy)Quantum decoherenceQuantumPhysicsContext (archaeology)Superposition principleMoleculeCoherence timeQuantum sensorQuantum imagingQuantum opticsQuantum superpositionQuantum mechanicsQuantum stateQuantum technologyOpen quantum systemPaleontologyBiologyStrong Light-Matter InteractionsMechanical and Optical ResonatorsQuantum Information and Cryptography