6533b82afe1ef96bd128b743

RESEARCH PRODUCT

Improved centrifugal and hyperfine analysis of ND2H and NH2D and its application to the spectral line survey of L1544

Paola CaselliLuca DoreZbigniew KisielMattia MelossoS. SpezzanoCristina PuzzariniNingjing JiangJürgen GaussLuca Bizzocchi

subject

Rotational spectroscopy010402 general chemistry01 natural sciencesStarless coreSpectral linelaw.inventionDeuterium fractionationAmmoniaInterstellar mediumlaw0103 physical sciencesPhysical and Theoretical ChemistryHyperfine structureAstrophysics::Galaxy AstrophysicsSpectroscopyLine (formation)010304 chemical physicsSpectrometerAtomic and Molecular Physics and OpticsSynchrotron0104 chemical sciencesComputational physicsInterstellar mediumDeuteriumHyperfine structureRotational spectroscopy

description

Abstract Quantifying molecular abundances of astrochemical species is a key step towards the understanding of the chemistry occurring in the interstellar medium. This process requires a profound knowledge of the molecular energy levels, including their structure resulting from weak interactions between nuclear spins and the molecular rotation. With the aim of increasing the quality of spectral line catalogs for the singly- and doubly-deuterated ammonia (NH2D and ND2H), we have revised their rotational spectra by observing many hyperfine-resolved lines and more accurate high-frequency transitions. The measurements have been performed in the submillimeter-wave region (265–1565 GHz) using a frequency modulation submillimeter spectrometer and in the far-infrared domain (45–220 cm−1) with a synchrotron-based Fourier-transform interferometer. The analysis of the new data, with the interpretation of the hyperfine structure supported by state-of-the-art quantum-chemical calculations, led to an overall improvement of all spectroscopic parameters. Moreover, the effect of the inclusion of deuterium splittings in the analysis of astrophysical NH2D emissions at millimeter wavelengths has been tested using recent observations of the starless core L1544, an ideal astrophysical laboratory for the study of deuterated species. Our results show that accounting for hyperfine interactions leads to a small but significant change in the physical parameters used to model NH2D line emissions.

https://doi.org/10.1016/j.jms.2021.111431