English

Enantioselective Topological Frequency Conversion

Quantum Physics 2022-03-08 v2

Abstract

Two molecules are enantiomers if they are non-superimposable mirror images of each other. Electric dipole-allowed cyclic transitions 1231|1\rangle\to|2\rangle\to|3\rangle\to|1\rangle obey the symmetry relation OR=OS\mathcal{O}^{R}=-\mathcal{O}^{S}, where OR,S=(μ21R,SE21)(μ13R,SE13)(μ32R,SE32)\mathcal{O}^{R,S}=(\mu_{21}^{R,S}E_{21})(\mu_{13}^{R,S}E_{13})(\mu_{32}^{R,S}E_{32}), and R,SR,S label the two enantiomers. Here we generalize the concept of topological frequency conversion to an ensemble of enantiomers. We show that, within a rotating-frame, the pumping power between fields of frequency ω1\omega_{1} and ω2\omega_{2} is sensitive to enantiomeric excess, P21=ω1ω2CLR2π(NRNS)\mathcal{P}_{2\to1}=\hbar\frac{\omega_{1}\omega_{2}C_{L}^{R}}{2\pi}(N_{R}-N_{S}), where NiN_{i} is the number of enantiomers ii and CLRC_{L}^{R} is an enantiomer-dependent Chern number. Connections with chiroptical microwave spectroscopy are made. Our work provides an underexplored and fertile connection between topological physics and molecular chirality.

Cite

@article{arxiv.2105.05469,
  title  = {Enantioselective Topological Frequency Conversion},
  author = {Kai Schwennicke and Joel Yuen-Zhou},
  journal= {arXiv preprint arXiv:2105.05469},
  year   = {2022}
}
R2 v1 2026-06-24T02:01:33.254Z