Spectral Signatures of Hydrogen Thioperoxide (HOSH) and Hydrogen Persulfide (HSSH): Possible Molecular Sulfur Sinks in the Dense ISM

Palmer, C. Zachary; Fortenberry, Ryan C.; Francisco, Joseph S.

doi:10.3390/molecules27103200

Cited by 4 publications

(6 citation statements)

References 80 publications

(98 reference statements)

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“…In order to assess the viability and persistence of the HOOF molecule for potential astronomical or atmospheric observation, the bond strengths of the HOOF are computed in this work, in kcal/mol, at the F12-TZ level and given in the following scheme: Comparing the O–O bond strength in HOOF to the previously computed O–O bond strength of HOOH, first observed in the ISM in 2011, shows good agreement with a difference of only 3.0 kcal/mol, suggesting this bond will persist after formation. The O–F bond strength, however, is much weaker at −31.53 kcal/mol, which is a 30% difference from the O–O bond strength of HOOH, calling into question its persistence.…”

Section: Resultsmentioning

confidence: 92%

“…In order to assess the viability and persistence of the HOOF molecule for potential astronomical or atmospheric observation, the bond strengths of the HOOF are computed in this work, in kcal/mol, at the F12-TZ level and given in the following scheme: 3. The data for both HOOH and HOSH come from a previous theoretical study 71 that also utilizes the F12-TZ QFF method to compute accurate vibrational frequencies. HOOH exhibits more intense vibrational transitions than either HOSH and HOOF with HOOH's largest being the torsional motion, ν 4 at 164 km/mol and its second largest being the antisymmetric H − O − O bend, ν 6 , at 119 km/mol.…”

Section: Resultsmentioning

confidence: 99%

“…Additionally, a comparison of the vibrational frequencies and dipole moments between HOOF and other peroxides such as HOOH and the theorized hydrogen thioperoxide (HOSH) molecule are given in Table . The data for both HOOH and HOSH come from a previous theoretical study that also utilizes the F12-TZ QFF method to compute accurate vibrational frequencies. HOOH exhibits more intense vibrational transitions than either HOSH and HOOF with HOOH’s largest being the torsional motion, ν 4 at 164 km/mol and its second largest being the antisymmetric H – O – O bend, ν 6 , at 119 km/mol.…”

Section: Resultsmentioning

confidence: 99%

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Fluoro Hydrogen Peroxide: A Plausible Molecular Form of Naturally-Occurring Fluorine

Palmer

Fortenberry

2022

ACS Earth Space Chem.

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Fluorine's hostile nucleosynthetic environment makes it one of the least common elements and, consequently, understudied both on the earth and in the interstellar medium (ISM). However, the presence of fluorine-containing species in both the ISM and in the earth's atmosphere necessitates the existence of a pathway out of this environment to form fluorinecontaining molecules. To that end, the presence of fluorine and hydroperoxyl radical (HO 2 ) in either of these environments may lead to the formation of fluorinated molecules like fluoro hydrogen peroxide (HOOF) on dust grains of protoplanetary disks in the planet-forming regions of ρ Oph and in the earth's atmosphere as a sink for other fluorine pollutants that have yet to be detected. This theoretical study utilizes explicitly correlated coupled cluster theory computed with core correlation and corrections from scalar relativity to provide the first anharmonic fundamental vibrational frequencies and rotational constants of HOOF for use as reference benchmarking of further computational or experimental study, as well as potential astrophysical observation. The ν 6 bending frequency for HOOF at 454.4 cm −1 exhibits an anharmonic transition intensity of 78 km/mol, while the ν 4 frequency at 738.2 cm −1 is 66 km/mol. Additionally, HOOF has a large net dipole moment of 2.12 D compared to the previously detected HF and HOOH molecules, 1.82 and 1.85 D, respectively, resulting from the electronegativity of the fluorine. Consequently, HOOF is a likely candidate for possible detection via vibrational and rotational spectroscopy to further the understanding of fluorine's small, but important, role in astrochemical and atmospheric environments.

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Section: Resultsmentioning

confidence: 92%

“…In order to assess the viability and persistence of the HOOF molecule for potential astronomical or atmospheric observation, the bond strengths of the HOOF are computed in this work, in kcal/mol, at the F12-TZ level and given in the following scheme: 3. The data for both HOOH and HOSH come from a previous theoretical study 71 that also utilizes the F12-TZ QFF method to compute accurate vibrational frequencies. HOOH exhibits more intense vibrational transitions than either HOSH and HOOF with HOOH's largest being the torsional motion, ν 4 at 164 km/mol and its second largest being the antisymmetric H − O − O bend, ν 6 , at 119 km/mol.…”

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Fluoro Hydrogen Peroxide: A Plausible Molecular Form of Naturally-Occurring Fluorine

Palmer

Fortenberry

2022

ACS Earth Space Chem.

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“…The present rovibrational study utilizes a QFF method based on CCSD(T) again within the explicitly correlated F12b formalism , conjoined to the corresponding cc-pVTZ-F12 basis set. This QFF is typically called “F12-TZ.” While the F12-TZ QFF has been used in the past to provide accurate anharmonic fundamental frequencies, − one of its major downfalls is its inability to calculate high-accuracy rotational constants. ,, In order to overcome the accuracy shortcomings in the rotational constants, a composite method is employed that combines the accuracy in the anharmonic frequencies from the F12-TZ method and the higher accuracies for the rotational constants achieved by a previous and well documented composite method . This QFF method utilized herein uses the CCSD(T)-F12b level with the inclusion of explicit core–electron correlation in the cc-pCVTZ-F12 basis set and scalar relativistic corrections also present in the previous composite methodology.…”

Section: Methodsmentioning

confidence: 99%

“…One drawback of the methodology implemented in the present vibrational study is the inability to effectively model the very floppy bends of the 1 3 A″ state of OAlNO, much like previously studied Alcontaining species, 68 and even HOOH. 58,87 For that reason, for the computed vibrational spectra, the untrustworthy cubic and quartic terms of coordinates 4 and 5 were removed for the 1 3 A″ state of OAlNO and the ∠(Al−N−O 2 ) and in-plane linear bend, respectively, from the VPT2 calculations. Even then, the vibrational spectrum contains some positive anharmonicities for ν 4 −ν 6 for OAlNO, but this is expected for near-prolate molecules.…”

Section: Stability and Bondingmentioning

confidence: 99%

Spectroscopy and Photochemistry of OAlNO and Implications for New Metal Chemistry in the Atmosphere

Esposito,

Palmer,

Fortenberry

et al. 2023

J. Phys. Chem. A

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A new aluminum-bearing species, OAlNO, which has the potential to impact the chemistry of the Earth’s upper atmosphere, is characterized via high-level, ab initio, spectroscopic methods. Meteor-ablated aluminum atoms are quickly oxidized to aluminum oxide (AlO) in the mesosphere and lower thermosphere (MLT), where a steady-state layer of AlO then builds up. Concurrent formation of nitric oxide (NO) in the same region of the atmosphere will lead to the bimolecular formation of the OAlNO molecule. Molecular orbital analysis provides fundamental insights into the chemical bonding and energetic arrangement of the triplet (1 3A″) ground state and singlet (1 1A′) excited-state species of OAlNO. Additionally, unpaired electrons on the terminal oxygen atom of triplet (1 3A″) OAlNO cause it to be reactive to atmospheric species, potentially impacting climate science and high-altitude chemistry. The triplet (1 3A″) ground-state species exhibits a large permanent dipole moment useful for rotational spectroscopic detection; however, similar rotational constants to the singlet (1 1A′) excited-state species will hamper differentiation in a spectrum. Strong infrared intensities will assist in detection and discrimination of the different spin states and isomers. Repulsive electronic excited states of OAlNO will lead to photolysis of the Al–N bond and formation of various electronic states of AlO + NO through nonadiabatic pathways. Reaction through the OAlNO intermediate represents a means for the production of electronically excited AlO, leading to new chemistry in the atmosphere. Excitation to higher-lying electronic states will lead to fluorescence with a minor Stokes shift, useful for laboratory investigation. Such physical properties of this molecule will allow for new, unexplored chemical pathways in the MLT to be considered.

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Theoretical Rotational and Vibrational Spectral Data for the Hypermagnesium Oxide Species Mg₂O and Mg₂O⁺

Flint,

Westbrook,

Fortenberry

2024

ChemPhysChem

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While magnesium is astronomically observed in small molecules, it largely serves as a contributor to silicate grains, though how these grains form is not well‐understood. The smallest hypermagnesium oxide compounds (Mg2O/Mg2O+) may play a role in silicate formation, but little vibrational reference data exist. As such, anharmonic spectroscopic data are computed for X 1Σ+g Mg2O, ã 3Σ+u Mg2O, and X2Σ+g Mg2O+ using quartic force fields (QFFs). Explicitly‐correlated coupled‐cluster QFFs for the neutral species perform well, implying that full multireference treatment may not be necessary for such systems if enough electron correlation is included. Equation‐of‐motion ionization potential (EOMIP) methods for X2Σ+g Mg2O+ QFFs circumvent previous symmetry breaking issues even in explicitly‐correlated coupled‐cluster results, motivating the need for EOMIP treatments at minimum for such systems. All three species are found to have high‐intensity vibrational frequencies. Even so, the highly intense fundamental (X 1Σ+g Mg2O: 894.7 cm‐1/11.18 μm; ã 3Σ+u Mg2O: 915.0 cm‐1/10.91 μm) for either neutral state may be astronomically obscured by the polycyclic aromatic hydrocarbon 11.2 μm band. Mg2O+ may be less susceptible to such obfuscation, and its ν1 intensity is computed to be a massive 4793 km mol‐1.

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Spectral Signatures of Hydrogen Thioperoxide (HOSH) and Hydrogen Persulfide (HSSH): Possible Molecular Sulfur Sinks in the Dense ISM

Cited by 4 publications

References 80 publications

Fluoro Hydrogen Peroxide: A Plausible Molecular Form of Naturally-Occurring Fluorine

Fluoro Hydrogen Peroxide: A Plausible Molecular Form of Naturally-Occurring Fluorine

Spectroscopy and Photochemistry of OAlNO and Implications for New Metal Chemistry in the Atmosphere

Theoretical Rotational and Vibrational Spectral Data for the Hypermagnesium Oxide Species Mg₂O and Mg₂O⁺

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Spectral Signatures of Hydrogen Thioperoxide (HOSH) and Hydrogen Persulfide (HSSH): Possible Molecular Sulfur Sinks in the Dense ISM

Cited by 4 publications

References 80 publications

Fluoro Hydrogen Peroxide: A Plausible Molecular Form of Naturally-Occurring Fluorine

Fluoro Hydrogen Peroxide: A Plausible Molecular Form of Naturally-Occurring Fluorine

Spectroscopy and Photochemistry of OAlNO and Implications for New Metal Chemistry in the Atmosphere

Theoretical Rotational and Vibrational Spectral Data for the Hypermagnesium Oxide Species Mg2O and Mg2O+

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Theoretical Rotational and Vibrational Spectral Data for the Hypermagnesium Oxide Species Mg₂O and Mg₂O⁺