Computational Infrared Spectroscopy of 958 Phosphorus-Bearing Molecules

Zapata Trujillo, JC; Syme, A-M; Rowell, KN; Burns, BP; Clark, ES; Gorman, MN; Jacob, LSD; Kapodistrias, P; Kedziora, DJ; Lempriere, FAR; Medcraft, C; O'Sullivan, J; Robertson, EG; Soares, GG; Steller, L; Teece, BL; Tremblay, CD; Sousa-Silva, C; McKemmish, LK

Computational Infrared Spectroscopy of 958 Phosphorus-Bearing Molecules

Zapata Trujillo, JC Syme, A-M Rowell, KN Burns, BP Clark, ES Gorman, MN Jacob, LSD Kapodistrias, P Kedziora, DJ Lempriere, FAR Medcraft, C O'Sullivan, J Robertson, EG Soares, GG Steller, L Teece, BL Tremblay, CD Sousa-Silva, C McKemmish, LK

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Publisher:: Frontiers Media SA
Publication Type:: Journal Article
Citation:: Frontiers in Astronomy and Space Sciences, 2021, 8, pp. 639068
Issue Date:: 2021-04-08

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Field	Value	Language
dc.contributor.author	Zapata Trujillo, JC
dc.contributor.author	Syme, A-M
dc.contributor.author	Rowell, KN
dc.contributor.author	Burns, BP
dc.contributor.author	Clark, ES
dc.contributor.author	Gorman, MN
dc.contributor.author	Jacob, LSD
dc.contributor.author	Kapodistrias, P
dc.contributor.author	Kedziora, DJ
dc.contributor.author	Lempriere, FAR
dc.contributor.author	Medcraft, C
dc.contributor.author	O'Sullivan, J
dc.contributor.author	Robertson, EG
dc.contributor.author	Soares, GG
dc.contributor.author	Steller, L
dc.contributor.author	Teece, BL
dc.contributor.author	Tremblay, CD
dc.contributor.author	Sousa-Silva, C
dc.contributor.author	McKemmish, LK
dc.date.accessioned	2021-04-26T05:27:27Z
dc.date.available	2021-04-26T05:27:27Z
dc.date.issued	2021-04-08
dc.identifier.citation	Frontiers in Astronomy and Space Sciences, 2021, 8, pp. 639068
dc.identifier.issn	2296-987X
dc.identifier.issn	2296-987X
dc.identifier.uri	http://hdl.handle.net/10453/148381
dc.description.abstract	<jats:p>Phosphine is now well-established as a biosignature, which has risen to prominence with its recent tentative detection on Venus. To follow up this discovery and related future exoplanet biosignature detections, it is important to spectroscopically detect the presence of phosphorus-bearing atmospheric molecules that could be involved in the chemical networks producing, destroying or reacting with phosphine. We start by enumerating phosphorus-bearing molecules (P-molecules) that could potentially be detected spectroscopically in planetary atmospheres and collecting all available spectral data. Gaseous P-molecules are rare, with speciation information scarce. Very few molecules have high accuracy spectral data from experiment or theory; instead, the best current spectral data was obtained using a high-throughput computational algorithm, RASCALL, relying on functional group theory to efficiently produce approximate spectral data for arbitrary molecules based on their component functional groups. Here, we present a high-throughput approach utilizing established computational quantum chemistry methods (CQC) to produce a database of approximate infrared spectra for 958 P-molecules. These data are of interest for astronomy and astrochemistry (importantly identifying potential ambiguities in molecular assignments), improving RASCALL's underlying data, big data spectral analysis and future machine learning applications. However, this data will probably not be sufficiently accurate for secure experimental detections of specific molecules within complex gaseous mixtures in laboratory or astronomy settings. We chose the strongly performing harmonic ωB97X-D/def2-SVPD model chemistry for all molecules and test the more sophisticated and time-consuming GVPT2 anharmonic model chemistry for 250 smaller molecules. Limitations to our automated approach, particularly for the less robust GVPT2 method, are considered along with pathways to future improvements. Our CQC calculations significantly improve on existing RASCALL data by providing quantitative intensities, new data in the fingerprint region (crucial for molecular identification) and higher frequency regions (overtones, combination bands), and improved data for fundamental transitions based on the specific chemical environment. As the spectroscopy of most P-molecules have never been studied outside RASCALL and this approach, the new data in this paper is the most accurate spectral data available for most P-molecules and represent a significant advance in the understanding of the spectroscopic behavior of these molecules.</jats:p>
dc.language	en
dc.publisher	Frontiers Media SA
dc.relation.ispartof	Frontiers in Astronomy and Space Sciences
dc.relation.isbasedon	10.3389/fspas.2021.639068
dc.rights	info:eu-repo/semantics/openAccess
dc.title	Computational Infrared Spectroscopy of 958 Phosphorus-Bearing Molecules
dc.type	Journal Article
utslib.citation.volume	8
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology
pubs.organisational-group	/University of Technology Sydney/Strength - AAI - Advanced Analytics Institute Research Centre
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology/A/DRsch The Data Science Institute
utslib.copyright.status	open_access	*
dc.date.updated	2021-04-26T05:27:25Z
pubs.publication-status	Published online
pubs.volume	8

Abstract:

Phosphine is now well-established as a biosignature, which has risen to prominence with its recent tentative detection on Venus. To follow up this discovery and related future exoplanet biosignature detections, it is important to spectroscopically detect the presence of phosphorus-bearing atmospheric molecules that could be involved in the chemical networks producing, destroying or reacting with phosphine. We start by enumerating phosphorus-bearing molecules (P-molecules) that could potentially be detected spectroscopically in planetary atmospheres and collecting all available spectral data. Gaseous P-molecules are rare, with speciation information scarce. Very few molecules have high accuracy spectral data from experiment or theory; instead, the best current spectral data was obtained using a high-throughput computational algorithm, RASCALL, relying on functional group theory to efficiently produce approximate spectral data for arbitrary molecules based on their component functional groups. Here, we present a high-throughput approach utilizing established computational quantum chemistry methods (CQC) to produce a database of approximate infrared spectra for 958 P-molecules. These data are of interest for astronomy and astrochemistry (importantly identifying potential ambiguities in molecular assignments), improving RASCALL's underlying data, big data spectral analysis and future machine learning applications. However, this data will probably not be sufficiently accurate for secure experimental detections of specific molecules within complex gaseous mixtures in laboratory or astronomy settings. We chose the strongly performing harmonic ωB97X-D/def2-SVPD model chemistry for all molecules and test the more sophisticated and time-consuming GVPT2 anharmonic model chemistry for 250 smaller molecules. Limitations to our automated approach, particularly for the less robust GVPT2 method, are considered along with pathways to future improvements. Our CQC calculations significantly improve on existing RASCALL data by providing quantitative intensities, new data in the fingerprint region (crucial for molecular identification) and higher frequency regions (overtones, combination bands), and improved data for fundamental transitions based on the specific chemical environment. As the spectroscopy of most P-molecules have never been studied outside RASCALL and this approach, the new data in this paper is the most accurate spectral data available for most P-molecules and represent a significant advance in the understanding of the spectroscopic behavior of these molecules.

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http://hdl.handle.net/10453/148381