Issue 47, 2023

Cryogenic fluorescence spectroscopy of oxazine ions isolated in vacuo

Abstract

Recent developments in fluorescence spectroscopy have made it possible to measure both absorption and dispersed fluorescence spectra of isolated molecular ions at liquid-nitrogen temperatures. Absorption is here obtained from fluorescence-excitation experiments and does not rely on ion dissociation. One large advantage of reduced temperature compared to room-temperature spectroscopy is that spectra are narrow, and they provide information on vibronic features that can better be assigned from theoretical simulations. We report on the intrinsic spectroscopic properties of oxazine dyes cooled to about 100 K. They include six cations (crystal violet, darrow red, oxazine-1, oxazine-4, oxazine-170 and nile blue) and one anion (resorufin). Experiments were done with a home-built setup (LUNA2) where ions are stored, mass-selected, cooled, and photoexcited in a cylindrical ion trap. We find that the Stokes shifts are small (14–50 cm−1), which is ascribed to rigid geometries, that is, there are only small geometrical changes between the electronic ground and excited states. However, both the absorption and the emission spectra of darrow-red cations are broader than those of the other ionic dyes, which is likely associated with a less symmetric electronic structure and more non-zero Franck–Condon factors for the vibrational progressions. In the case of resorufin, the smallest ion under study, vibrational features are assigned based on calculated spectra.

Graphical abstract: Cryogenic fluorescence spectroscopy of oxazine ions isolated in vacuo

Supplementary files

Article information

Article type
Paper
Submitted
07 ربيع الأول 1445
Accepted
07 جمادى الأولى 1445
First published
08 جمادى الأولى 1445

Phys. Chem. Chem. Phys., 2023,25, 32715-32722

Cryogenic fluorescence spectroscopy of oxazine ions isolated in vacuo

C. Kjær, E. Vogt, J. Langeland, N. F. Christensen, T. T. Lindkvist, H. G. Kjaergaard and S. B. Nielsen, Phys. Chem. Chem. Phys., 2023, 25, 32715 DOI: 10.1039/D3CP04615J

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