VUV Spectroscopic Study of the D^1\Pi State of Molecular Deuterium

TL;DR

This study uses VUV Fourier-transform spectroscopy and photon-induced fluorescence to investigate the D^1 state of molecular deuterium, providing detailed measurements of vibrational levels, predissociation effects, and theoretical comparisons.

Contribution

It offers a comprehensive experimental and theoretical analysis of the D^1 state in molecular deuterium, including new high-resolution spectral data and validation of MQDT calculations.

Findings

Observation of Q-branch transitions up to v=23

Measurement of predissociation widths and Fano parameters

Validation of ab initio MQDT calculations within 0.5 cm^-1

Abstract

The D^1\Pi_u - X^1\Sigma_g^+ absorption system of molecular deuterium has been re-investigated using the VUV Fourier -Transform (FT) spectrometer at the DESIRS beamline of the synchrotron SOLEIL and photon-induced fluorescence spectrometry (PIFS) using the 10 m normal incidence monochromator at the synchrotron BESSY II. Using the FT spectrometer absorption spectra in the range 72 - 82 nm were recorded in quasi static gas at 100 K and in a free flowing jet at a spectroscopic resolution of 0.50 and 0.20 cm^{-1} respectively . The narrow Q-branch transitions, probing states of \Pi^- symmetry, were observed up to vibrational level v = 22. The states of \Pi^+ symmetry, known to be broadened due to predissociation and giving rise to asymmetric Beutler-Fano resonances, were studied up to v = 18. The 10 m normal incidence beamline setup at BESSY II was used to simultaneously record absorption, dissociation, ionization and fluorescence decay channels from which information on the line intensities, predissociated widths, and Fano q-parameters were extracted. R-branch transitions were observed up to v = 23 for J = 1-3 as well as several transitions for J = 4 and 5 up to v = 22 and 18 respectively. The Q-branch transitions are found to weakly predissociate and were observed from v = 8 to the final vibrational level of the state v = 23. The spectroscopic study is supported by two theoretical frameworks. Results on the \Pi^- symmetry states are compared to ab initio multi-channel-quantum defect theory (MQDT) calculations, demonstrating that these calculations are accurate to within 0.5 cm^-1.