Clusters of Exceptional Points for a Laser Control of Selective Vibrational Transfer

TL;DR

This paper maps clusters of Exceptional Points in laser parameters for H$_2^+$, enabling new vibrational transfer strategies aimed at molecular vibrational cooling.

Contribution

It provides an exhaustive map of exceptional point clusters in H$_2^+$, facilitating advanced vibrational transfer scenarios using multiple EPs.

Findings

Clusters of EPs can be used for vibrational transfer

Multiple vibrational quanta can be exchanged

Potential for molecular vibrational cooling

Abstract

When a molecule is exposed to a laser field, all field-free vibrational states become resonances, with complex quasi energies calculated using Floquet theory. There are many ways to produce the coalescences of pairs of such quasi energies, with appropriate wavelength-intensity choices which define Exceptional Points (EP) in the laser parameter plane. We dress for the molecular ion H$_2^+$ an exhaustive map of these exceptional points which appear in clusters. Such clusters can be used to define several vibrational transfer scenarios implying more than a single exceptional point, exchanging single or multiple vibrational quanta. The ultimate goal is molecular vibrational cooling by transferring an initial (thermal, for instance) population on a final (ground, for instance) single vibrational state. When a molecule is exposed to a laser field, all field-free vibrational states become resonances, with complex quasi energies calculated using Floquet theory. There are many ways to produce the coalescences of pairs of such quasi energies, with appropriate wavelength-intensity choices which define Exceptional Points (EP) in the laser parameter plane. We dress for the molecular ion H$_2^+$ an exhaustive map of these exceptional points which appear in clusters. Such clusters can be used to define several vibrational transfer scenarios implying more than a single exceptional point, exchanging single or multiple vibrational quanta. The ultimate goal is molecular vibrational cooling by transferring an initial (thermal, for instance) population on a final (ground, for instance) single vibrational state.