Computational Infrared Spectroscopy of 958 Phosphorus-Bearing Molecules

Trujilo, Juan C. Zapata; Syme, Anna-Maree; Rowell, Keiran; Burns, Brendan P.; Clark, Ebubekir S.; Gorman, Maire N.; Jacob, Lorrie; Kapodistrias, Panayioti; Kedziora, David J.; Lempriere, Felix A. R.; O'Sullivan, J. P.; Robertson, Evan G.; Soares, Georgia G.; Steller, Luke; Teece, Bronwyn L.; Tremblay, Chenoa D.; Sousa-Silva, Clara; McKemmish, Laura K.

doi:10.3389/fspas.2021.639068

Cited by 11 publications

(9 citation statements)

References 166 publications

(260 reference statements)

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“…Routine quantum chemistry calculations, e.g., harmonic and anharmonic frequency calculations, have the potential to enable high-throughput approaches for producing approximate spectral data for thousands of molecules of astrochemistry interest . However, it is currently unclear what model chemistry should be used and what errors in frequency predictions should be expected; this is essential information to help assess the usefulness of these high-throughput calculations to astrochemistry.…”

Section: Discussionmentioning

confidence: 99%

“…Definitive remote detection of molecular species in different astronomical settings, e.g., (exo)planetary atmospheres, relies on the availability of high-resolution spectroscopic data, − which is very time-intensive to produce. As a complementary approach, it is likely to be useful to obtain approximate data for the thousands of molecular species of interest astrophysically, e.g., as discussed by Seager et al Though this novel approach , cannot enable definitive molecular detections, there are nevertheless many anticipated applications of this big data including identification of molecules with strong absorption (that will be easier to detect), recognizing potential ambiguities in molecular detections over some spectral windows, understanding the relative congestion of signals at different frequencies, and providing data for machine learning of vibrational frequencies.…”

Section: Introductionmentioning

confidence: 99%

“…An obvious way to produce this approximate vibrational spectral data for thousands of molecules is through harmonic or anharmonic quantum chemistry vibrational frequency calculations, as piloted by Zapata Trujillo et al However, existing literature, as recently reviewed by Zapata Trujillo and McKemmish, does not provide a definitive recommendation for a quantum chemistry methodology, even within the extremely popular harmonic approximation, nor does it explore the likely errors. These recommendations and error analysis are of interest far beyond the astrochemistry community (as evidenced by high citation numbers of, for example, Scott and Radom).…”

Section: Introductionmentioning

confidence: 99%

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VIBFREQ1295: A New Database for Vibrational Frequency Calculations

Trujillo

McKemmish

2022

J. Phys. Chem. A

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High-throughput approaches for producing approximate vibrational spectral data for molecules of astrochemistry interest rely on harmonic frequency calculations using computational quantum chemistry. However, model chemistry recommendations (i.e., a level of theory and basis set pair) for these calculations are not yet available and, thus, thorough benchmarking against comprehensive benchmark databases is needed. Here, we present a new database for vibrational frequency calculations (VIBFREQ1295) storing 1295 experimental fundamental frequencies and CCSD(T)(F12*)/cc-pVDZ-F12 ab initio harmonic frequencies from 141 molecules. VIBFREQ1295’s experimental data was complied through a comprehensive review of contemporary experimental data, while the ab initio data was computed here. The chemical space spanned by the molecules chosen is considered in-depth and is shown to have good representation of common organic functional groups and vibrational modes. Scaling factors are routinely used to approximate the effect of anharmonicity and convert computed harmonic frequencies to predicted fundamental frequencies. With our experimental and high-level ab initio data, we find that a single global uniform scaling factor of 0.9617(3) results in median differences of 15.9(5) cm–1. A far superior performance with a median difference of 7.5(5) cm–1 can be obtained, however, by using separate scaling factors (SFs) for three regions: frequencies less than 1000 cm–1 (SF = 0.987(1)), between 1000 and 2000 cm–1 (SF = 0.9727(6)), and above 2000 cm–1 (SF = 0.9564(4)). This sets a lower bound for the performance that could be reliably obtained using scaling of harmonic frequency calculations to predict experimental fundamental frequencies. VIBFREQ1295’s most important purpose is to provide a robust database for benchmarking the performance of any vibrational frequency calculations. VIBFREQ1295 data could also be used to train machine-learning models for the prediction of vibrational spectra and as a reference and data starting point for more detailed spectroscopic modeling of particular molecules. The database can be found as part of the Supporting Information for this paper or in the Harvard DataVerse at .

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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VIBFREQ1295: A New Database for Vibrational Frequency Calculations

Trujillo

McKemmish

2022

J. Phys. Chem. A

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“…Today, vibrational frequency calculations are one of the most routinely performed quantum chemistry calculations 3–11 . Arguably, their most common application is aiding in the interpretation of experimental vibrational spectra, where the computational predictions support accurate band assignments, especially for larger molecules with complex vibrational spectral patterns 12–17 .…”

Section: Introductionmentioning

confidence: 99%

Meta‐analysis of uniform scaling factors for harmonic frequency calculations

Trujillo

McKemmish

2021

WIREs Comput Mol Sci

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Vibrational frequency calculations performed under the harmonic approximation are widespread across chemistry. However, it is well‐known that the calculated harmonic frequencies tend to systematically overestimate experimental fundamental frequencies; a limitation commonly overcome with multiplicative scaling factors. In practice, multiplicative scaling factors are derived for each individual model chemistry choice (i.e., a level of theory and basis set pair), where performance is judged by, for example, the root‐mean square error (RMSE) between the predicted scaled and experimental frequencies. However, despite the overwhelming number of scaling factors reported in the literature and model chemistry approximations available, there is little guidance for users on appropriate model chemistry choices for harmonic frequency calculations. Here, we compile and analyze the data for 1495 scaling factors calculated using 141 levels of theory and 109 basis sets. Our meta‐analysis of this data shows that scaling factors and RMSE approach convergence with only hybrid functionals and double‐zeta basis sets, with anharmonicity error already dominating model chemistry errors. Noting inconsistent data and the lack of independent testing, we can nevertheless conclude that a minimum error of 25 cm−1—arising from insufficiently accurate treatment of anharmonicity—is persistent regardless of the model chemistry choice. Based on the data we compiled and cautioning the need for a future systematic benchmarking study, we recommend ωB97X‐D/def2‐TZVP for most applications and B2PLYP/def2‐TZVPD for superior intensity predictions. With a smaller benchmark set, direct comparison prefers ωB97X‐D/6‐31G* to B3LYP/6‐31G*. This article is categorized under: Electronic Structure Theory > Density Functional Theory Theoretical and Physical Chemistry > Spectroscopy

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“…Following this discovery, (Zapata Trujillo et al 2021) noted the importance of being able to detect spectroscopically the presence of phosphorous bearing species. They enumerated a list of phosphorous bearing species, which could potentially be detected in planetary atmospheres, and compiled all available spectral data.…”

Section: Introductionmentioning

confidence: 99%

A large-scale approach to modelling Biosignatures: First Steps

Cross¹,

Pignatari²,

Benoit³

et al. 2024

Preprint

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<p>For this poster I will be presenting the approaches taken to produce synthetic spectra for molecules believed to be biosignatures. In astrochemistry, biosignatures describe a group of molecules which could be produced by life and therefore act as an indication of it. Naturally, by being able to identify these molecules it will be possible to screen exoplanets for the possibility of harbouring life.&#160;</p> <p>Recently, Seager, Bains and Petkowski (2016) produced a catalogue of possible biosignatures, which totalled above 14,000 molecules. There are groups such as the ExoMol group which model these molecules at extremely high precision. However, due to the large number of molecules, a high precision method would take an unreasonable amount of time and therefore a faster means of producing spectra is required. The work shown within is designed to be quick and produce data for the full rovibronic spectrum rather than selected bands. I will show that anharmonic corrections are needed to be able to simulate qualitatively correct ro-vibrational transitions. In my method, this is done by implementing TOSH, transition optimised shifted hermites, which was first detailed by Lin, Gilbert and Gill (2007). Finally I will be presenting my latest results using this analytical anharmonic approach.&#160;</p>

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Computational Infrared Spectroscopy of 958 Phosphorus-Bearing Molecules

Cited by 11 publications

References 166 publications

VIBFREQ1295: A New Database for Vibrational Frequency Calculations

VIBFREQ1295: A New Database for Vibrational Frequency Calculations

Meta‐analysis of uniform scaling factors for harmonic frequency calculations

A large-scale approach to modelling Biosignatures: First Steps

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