Rate constant calculations of the GeH4 + OH/OD → GeH3 + H2O/HOD reactions using an ab initio based full-dimensional potential energy surface

Espinosa‐García, J.; Rangel, Cipriano; Corchado, J. C.

doi:10.1039/c6cp02986h

Cited by 13 publications

(7 citation statements)

References 52 publications

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“…The section finishes with a comparison of the kinetics behavior of the OH free radical with IV group hydrides, OH + XH 4 (X≡C, Si, Ge), which has been investigated in our lab 51,52 . As noted in Section 1, the corresponding broken X–H dissociation energies decrease in the series.…”

Section: Kinetics Results and Discussionmentioning

confidence: 91%

Kinetics study of the OH + SiH₄ hydrogen abstraction reaction: A theoretical analysis

Espinosa‐García

2022

Int J of Chemical Kinetics

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The temperature dependence of the rate constants and the kinetics isotope effects of the OH + SiH4 hydrogen abstraction reaction were theoretically studied. Three different kinetics approaches were used in this study: variational transition state theory with multidimensional tunneling (VTST/MT) corrections, quasi‐classical trajectory (QCT) calculations, and ring polymer molecular dynamics (RPMD). These studies were performed on a global analytical potential energy surface based on explicitly correlated high level ab initio calculations developed in the present work. While the experimental rate constants are practically independent with temperature, the VTST/MT results show a pronounced dependence, the QCT partially corrects this behavior, and RPMD rates are in better agreement with experiment. In this case, in the experimental common temperature range, 300–600 K, the T‐expression for the RPMD rate constants is: k(T) = 6.40 × 10−13.T0.52exp(−0.10/T). The kinetics isotope effects, H/D, are small in this temperature range, revealing the small importance of tunneling effects in this very exothermic and low barrier reaction. Different factors, such as anharmonicity, the zero‐point violation problem or limitations of the surface, without ruling out experimental uncertainties, were analyzed to explain the discrepancies.

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Section: Kinetics Results and Discussionmentioning

confidence: 91%

Kinetics study of the OH + SiH₄ hydrogen abstraction reaction: A theoretical analysis

Espinosa‐García

2022

Int J of Chemical Kinetics

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“…The use of scale factor has been usually considered to be adequate for anharmonicity correction, for example, see refs and . In the case of 3 INTb, which possesses a torsional degree of freedom, torsional anharmonicity was included by treating the lowest vibrational frequency as a hindered rotor, while the other frequencies were treated as separable harmonic oscillators modified by a frequency scale factor . No multistructural anharmonicity was concerned because all reactants, products, TSs, and intermediates could be described by a single structure .…”

Section: Results and Discussionmentioning

confidence: 99%

“…However, a contradiction is evident in Figure ; MESMER and the study of Hickson et al show negative temperature dependency at lower temperatures and positive temperature dependency at higher temperatures, while RRKM–SSA flags positive temperature dependency over the entire range of temperature. Negative temperature dependency is probable for the reactions of free radicals and atomic or ionic species that form a stabilized reactant complex in their entrance channels . On the other hand, the presence of positive apparent activation energy enforces positive temperature dependency .…”

Section: Results and Discussionmentioning

confidence: 99%

“…In the case of 3 INTb, which possesses a torsional degree of freedom, torsional anharmonicity was included by treating the lowest vibrational frequency as a hindered rotor, while the other frequencies were treated as separable harmonic oscillators modified by a frequency scale factor. 103 No multistructural anharmonicity was concerned because all reactants, products, TSs, and intermediates could be described by a single structure. 102 The applied anharmonicity corrections are expected to influence kinetics of the reaction in two ways: 104 (i) declining the effect of dividing surface position on the rate coefficients by decreasing the effect of transitional modes and approaching the maximal Gibbs free energy change of the corresponding reaction coordinate to the saddle point and (ii) lowering the rate coefficients depending on the studied reaction and temperature.…”

Section: ■ Methodsmentioning

confidence: 99%

“…Negative temperature dependency is probable for the reactions of free radicals and atomic or ionic species that form a stabilized reactant complex in their entrance channels. 103 On the other hand, the presence of positive apparent activation energy enforces positive temperature dependency. 121 Furthermore, the presence of barrier heights at the entrance channel might invoke tunneling at low temperatures and lead to negative temperature dependency.…”

Section: The Journal Of Physical Chemistry Amentioning

confidence: 99%

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Chemical Kinetics Approves the Occurrence of C (³P_j) Reaction with H₂O

Keshavarz

2019

J. Phys. Chem. A

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Although both atomic carbon and water are omnipresent in human life, there is a debate about the possibility of carbon reaction with water. Some low-temperature spectroscopic investigations have rejected the reaction, whereas some room-temperature experiments and theoretical studies have accepted the possibility of the reaction by reporting rate coefficients ranging from 105 to 109 L mol–1 s–1. This study provides new lines of evidence about the reaction through exploration of the reaction mechanism using the CCSD(T) method and solving the corresponding master equation by following two main approaches. According to the results, the rate coefficient of the reaction is significantly influenced by the tunneling and hindered rotation effects, in addition to the selected total angular momentum (J). Furthermore, the total rate coefficient of the reaction increases dramatically (from 107 to 1011 L mol–1 s–1) with the rise of temperature from 100 to 4000 K, while the total rate coefficient is insensitive to pressure (0.1–10 atm). Despite some differences between the results of the two approaches, the rate coefficients of both methods are consistent with the previously reported rate coefficients. Also, in agreement with the previous studies, the major products are 2HOC + 2H and 2HCO + 2H. In general, the findings approve the occurrence of the title reaction and indicate that the mentioned conflict is due to the sensitivity of the reaction to the investigated temperature and J level. The sensitivity does not permit low-temperature spectroscopic studies to detect any products and varies the measured and calculated rate coefficients.

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Gas Phase Formation of Methylgermylene (HGeCH3)

Yang

Doddipatla

et al. 2020

ChemPhysChem

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The methylgermylene species (HGeCH3; X1A′) has been synthesized via the bimolecular gas phase reaction of ground state methylidyne radicals (CH) with germane (GeH4) under single collision conditions in crossed molecular beams experiments. Augmented by electronic structure calculations, this elementary reaction was found to proceed through barrierless insertion of the methylidyne radical in one of the four germanium‐hydrogen bonds on the doublet potential energy surface yielding the germylmethyl (CH2GeH3; X2A′) collision complex. This insertion is followed by a hydrogen shift from germanium to carbon and unimolecular decomposition of the methylgermyl (GeH2CH3; X2A′) intermediate by atomic hydrogen elimination leading to singlet methylgermylene (HGeCH3; X1A′). Our investigation provides a glimpse at the largely unknown reaction dynamics and isomerization processes of the carbon‐germanium system, which are quite distinct from those of the isovalent carbon system thus providing insights into the intriguing chemical bonding of organo germanium species on the most fundamental, microscopic level.

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Rate constant calculations of the GeH₄ + OH/OD → GeH₃ + H₂O/HOD reactions using an ab initio based full-dimensional potential energy surface

Cited by 13 publications

References 52 publications

Kinetics study of the OH + SiH₄ hydrogen abstraction reaction: A theoretical analysis

Kinetics study of the OH + SiH₄ hydrogen abstraction reaction: A theoretical analysis

Chemical Kinetics Approves the Occurrence of C (³P_j) Reaction with H₂O

Gas Phase Formation of Methylgermylene (HGeCH3)

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Rate constant calculations of the GeH4 + OH/OD → GeH3 + H2O/HOD reactions using an ab initio based full-dimensional potential energy surface

Cited by 13 publications

References 52 publications

Kinetics study of the OH + SiH4 hydrogen abstraction reaction: A theoretical analysis

Kinetics study of the OH + SiH4 hydrogen abstraction reaction: A theoretical analysis

Chemical Kinetics Approves the Occurrence of C (3Pj) Reaction with H2O

Gas Phase Formation of Methylgermylene (HGeCH3)

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Product

Resources

About

Rate constant calculations of the GeH₄ + OH/OD → GeH₃ + H₂O/HOD reactions using an ab initio based full-dimensional potential energy surface

Kinetics study of the OH + SiH₄ hydrogen abstraction reaction: A theoretical analysis

Kinetics study of the OH + SiH₄ hydrogen abstraction reaction: A theoretical analysis

Chemical Kinetics Approves the Occurrence of C (³P_j) Reaction with H₂O