Non-Hermitian Hamiltonians for linear and nonlinear optical response: A model for plexcitons

In polaritons, the properties of matter are modified by mixing the molecular transitions with light modes inside a cavity. Resultant hybrid light–matter states exhibit energy level shifts, are delocalized over many molecular units, and have a different excited-state potential energy landscape, which...

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Bibliographic Details
Published in:The Journal of chemical physics 2023-03, Vol.158 (10), p.104104-104104
Main Authors: Finkelstein-Shapiro, Daniel, Mante, Pierre-Adrien, Balci, Sinan, Zigmantas, Donatas, Pullerits, Tõnu
Format: Article
Language:English
Subjects:
Atom and Molecular Physics and Optics
Atom- och molekylfysik och optik
Chemical Sciences
Eigenvalues
Electronic systems
Energy levels
Excitation
Excitons
Feynman diagrams
Fysik
Hamiltonian functions
Kemi
Line shape
Natural Sciences
Naturvetenskap
Nonlinear optics
Nonlinear response
Operators
Optical properties
Physical Sciences
Plasmons
Polaritons
Potential energy
Response functions
Spectrum analysis
Symmetry
Teoretisk kemi
Theoretical Chemistry
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Summary:In polaritons, the properties of matter are modified by mixing the molecular transitions with light modes inside a cavity. Resultant hybrid light–matter states exhibit energy level shifts, are delocalized over many molecular units, and have a different excited-state potential energy landscape, which leads to modified exciton dynamics. Previously, non-Hermitian Hamiltonians have been derived to describe the excited states of molecules coupled to surface plasmons (i.e., plexcitons), and these operators have been successfully used in the description of linear and third order optical response. In this article, we rigorously derive non-Hermitian Hamiltonians in the response function formalism of nonlinear spectroscopy by means of Feshbach operators and apply them to explore spectroscopic signatures of plexcitons. In particular, we analyze the optical response below and above the exceptional point that arises for matching transition energies for plasmon and molecular components and study their decomposition using double-sided Feynman diagrams. We find a clear distinction between interference and Rabi splitting in linear spectroscopy and a qualitative change in the symmetry of the line shape of the nonlinear signal when crossing the exceptional point. This change corresponds to one in the symmetry of the eigenvalues of the Hamiltonian. Our work presents an approach for simulating the optical response of sublevels within an electronic system and opens new applications of nonlinear spectroscopy to examine the different regimes of the spectrum of non-Hermitian Hamiltonians.
ISSN:0021-9606
1089-7690
DOI:10.1063/5.0130287