Excited-state vibration-polariton transitions and dynamics in nitroprusside-Reference-Cited by-同舟云学术

Excited-state vibration-polariton transitions and dynamics in nitroprusside

Published:2021-01-11 Issue:1 Volume:12 Page:
ISSN:2041-1723
Container-title:Nature Communications
language:en
Short-container-title:Nat Commun

Author:

Grafton Andrea B.,Dunkelberger Adam D.,Simpkins Blake S.^ORCID,Triana Johan F.^ORCID,Hernández Federico J.^ORCID,Herrera Felipe,Owrutsky Jeffrey C.^ORCID

Abstract

AbstractStrong cavity coupling to molecular vibrations creates vibration-polaritons capable of modifying chemical reaction kinetics, product branching ratios, and charge transfer equilibria. However, the mechanisms impacting these molecular processes remain elusive. Furthermore, even basic elements determining the spectral properties of polaritons, such as selection rules, transition moments, and lifetimes are poorly understood. Here, we use two-dimensional infrared and filtered pump–probe spectroscopy to report clear spectroscopic signatures and relaxation dynamics of excited vibration-polaritons formed from the cavity-coupled NO band of nitroprusside. We apply an extended multi-level quantum Rabi model that predicts transition frequencies and strengths that agree well with our experiment. Notably, the polariton features decay ~3–4 times slower than the polariton dephasing time, indicating that they support incoherent population, a consequence of their partial matter character.

Funder

United States Department of Defense | United States Navy | Office of Naval Research

Publisher

Springer Science and Business Media LLC

Subject

General Physics and Astronomy,General Biochemistry, Genetics and Molecular Biology,General Chemistry

Link

http://www.nature.com/articles/s41467-020-20535-z.pdf

Reference59 articles.

1. Lidzey, D. G. & Coles, D. M. In Organic and Hybrid Photonic Crystals (ed. Commoretto, D.) 243–273 (Springer, Switzerland, 2015).

2. Litinskaya, M., Reineker, P. & Agranovich, V. M. Fast polariton relaxation in strongly coupled organic microcavities. J. Lumin. 110, 364–372 (2004).

3. Hutchison, J., Schwartz, T., Genet, C., Devaux, E. & Ebbeseen, T. W. Modifying chemical landscapes by coupling to vacuum fields. Angew. Chem. Int. Ed. 51, 1592–1596 (2012).

4. Munkhbat, B., Wersall, M., Baranov, D. G., Antosiewicz, T. J. & Shegai, T. Suppression of photo-oxidation of organic chromophores by strong coupling to plasmonic nanoantennas. Sci. Adv. 4, aas9552 (2018).

5. Lidzey, D. G. et al. Strong exciton-photon coupling in an organic semiconductor microcavity. Nature 395, 53–55 (1998).

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