Issue 35, 2024

Laser induced fluorescence spectroscopy of the transition of jet cooled 14NO3 and 15NO3 II: the dispersed fluorescence spectrum from the 3rd E level of the ν4 mode (approximately the 2ν4 (e′), l = 0, level)

Abstract

14NO3 and 15NO3 isotopomers were generated in a supersonic free jet expansion, and laser induced fluorescence (LIF) of the Image ID:d4cp01719f-t2.gif electronic transition was observed. Dispersed LIF spectra from the vibronic level at ∼770 cm−1 above the vibrationless level have been measured for each isotopomer. One remarkable characteristic of the dispersed fluorescence (DF) spectrum is that the ν2Image ID:d4cp01719f-t3.gif fundamental is clearly observed, even though the transition 201 is forbidden in the Image ID:d4cp01719f-t4.gif electronic transition. Another is that two sets of vibrational structure are observed in the DF spectrum: one of the two sets is the structure with the origin at the excitation energy, and the other is that with the origin at the ν2 fundamental. These observations suggest that the fluorescent level has contribution from the ν2 mode. In part I (M. Fukushima, J. Mol. Spectrosc., 2022, 387, 111646), it has been reported that the ν4 progressions are one of the typical characteristics of the vibrational structure of the DF spectrum from the vibrationless level; the progressions have intensity gradually decreasing with increasing ν4 quantum number (named the “regular” distribution), and have members forbidden for the Δl = 0 selection rule. The intensity distribution of the ν4 progression with the origin at the ν2 fundamental is similar to that from the vibrationless level, while that with the origin at the excitation energy is drastically different from that from the vibrationless level. The Jahn–Teller (J–T) and Renner–Teller (R–T) interactions in the [B with combining tilde]2E′ state enable us to interpret the intensity distributions of the ν4 progressions, in which relatively weak interactions are enough to reproduce the observed distributions. The spectral intensity distribution analyses adopting the two vibronic couplings suggest that the fluorescent level at ∼770 cm−1 above the vibrationless level is the 3rd E eigenstate of the ν4 mode. The major component of the ν4 3rd E state is the |Λ = ±1; v4 = 2, l4 = 0〉 level of the [B with combining tilde]2E′ state, which is a vibrationally Image ID:d4cp01719f-t5.gif and a vibronically E′ level, and it is therefore concluded that the major components of the fluorescent level are both of the ν2 = 1 level and ν4 = 2 level Image ID:d4cp01719f-t6.gif.

Graphical abstract: Laser induced fluorescence spectroscopy of the transition of jet cooled 14NO3 and 15NO3 II: the dispersed fluorescence spectrum from the 3rd E level of the ν4 mode (approximately the 2ν4 (e′), l = 0, level)

Supplementary files

Article information

Article type
Paper
Submitted
26 Apr 2024
Accepted
11 Aug 2024
First published
15 Aug 2024

Phys. Chem. Chem. Phys., 2024,26, 23307-23321

Laser induced fluorescence spectroscopy of the Image ID:d4cp01719f-t1.gif transition of jet cooled 14NO3 and 15NO3 II: the dispersed fluorescence spectrum from the 3rd E level of the ν4 mode (approximately the 2ν4 (e′), l = 0, level)

M. Fukushima, Phys. Chem. Chem. Phys., 2024, 26, 23307 DOI: 10.1039/D4CP01719F

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