Implementation of a variational code for the calculation of rate constants and application to barrierless dissociation and radical recombination reactions: CH<sub>3</sub>OH = CH<sub>3</sub> + OH

Oliveira, Roberta Camargos de; Bauerfeldt, Glauco F.

doi:10.1002/qua.24250

Cited by 13 publications

(13 citation statements)

References 54 publications

(59 reference statements)

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“…A series of 10 ethyl 4- or 3-X-cinnamates were synthesized from 4- or 3-X-cinnamic acid with ethanol, in accordance with the literature [10], where X = 4-OCH 3 , 4-OH, 4-CH 3 electron donor groups (EDGs), 3-F, 3-NO 2 , 4-Cl, 4-F, 4-CN, 4-NO 2 electron withdrawing (EWGs) groups and X = H. The reactions were conducted under reflux for 30 h using sulfuric acid as catalyst, to furnish the ethyl 4- or 3-X-cinnamates in good yields (45%–80%), and that the compounds with EWGs presented the best results. The compounds were obtained in trans geometry, being confirmed by the values of the coupling constant ( J ) of the olefinic hydrogens in the range of 15.0–16.5 Hz [47].…”

Section: Resultsmentioning

confidence: 99%

“…These can be expressed as charges, highest occupied molecular orbital (HOMO) and unoccupied molecular orbital (LUMO) energies, (HOMO-LUMO gap), Fukui function, and FERMOS (Frontier Effective-for-Reaction Molecular Orbitals) quantum descriptors [7]. Due to the importance of the cinnamates, and considering the interest both in studying the electronic effects arising from different substituents in cinnamoyl moiety [8,9] and in investigating the fundamental aspects that can elucidate the dynamic of chemical reactions [10,11], we report here theoretical-experimental results with the aim of describing a selection of quantum descriptors for the local hardness of carbonyl in the 4- and 3-substituted-cinnamic acid esterification being the substituents effects measured by quantitative structure–property relationship (QSPR). In order to assess such quantum descriptors, theoretical calculations have been performed at the density functional theory (DFT) level for a series of ethyl 4- and 3-substituted-cinnamates.…”

Section: Introductionmentioning

confidence: 99%

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Quantitative Structure–Property Relationship (QSPR) Models for a Local Quantum Descriptor: Investigation of the 4- and 3-Substituted-Cinnamic Acid Esterification

et al. 2015

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Abstract:In this work, the theoretical description of the 4-and 3-substituted-cinnamic acid esterification with different electron donating and electron withdrawing groups was performed at the B3LYP and M06-2X levels, as a two-step process: the O-protonation and the nucleophile attack by ethanol. In parallel, an experimental work devoted to the synthesis and characterization of the substituted-cinnamate esters has also been performed. In order to quantify the substituents effects, quantitative structure-property relationship (QSPR) models based on the atomic charges, Fukui functions and the Frontier Effective-for-Reaction Molecular Orbitals (FERMO) energies were investigated. In fact, the Fukui functions, ƒ + C and ƒ − O, indicated poor correlations for each individual step, and in contrast with the general literature, the O-protonation step is affected both by the FERMO energies and the O-charges of the carbonyl group. Since the process was shown to not be totally described by either charge-or frontier-orbitals, it is proposed to be frontier-charge-miscere controlled. Moreover, the observed OPEN ACCESSMolecules 2015, 20 17494 trend for the experimental reaction yields suggests that the electron withdrawing groups favor the reaction and the same was observed for Step 2, which can thus be pointed out as the determining step.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quantitative Structure–Property Relationship (QSPR) Models for a Local Quantum Descriptor: Investigation of the 4- and 3-Substituted-Cinnamic Acid Esterification

et al. 2015

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“…It is of course possible to calculate rate constants using molecular dynamics or other methods . However, calculations are normally limited to reactions involving a small number of nuclei.…”

Section: Discussionmentioning

confidence: 99%

“…However, calculations are normally limited to reactions involving a small number of nuclei. Published results are for particular reactions of interest, never for a whole class of reactions involving many nuclei. It is unlikely that values for many rate constants could be obtained in this way.…”

Section: Discussionmentioning

confidence: 99%

Rate Constants and Sticking Coefficients for H₂ and He Obtained by Analysis of Agglomeration in a Nozzle Beam

Goodisman

Chaiken

2016

Int J of Chemical Kinetics

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Cluster-cluster reaction rate constants are obtained from measurements of coalescence in nozzle-beam expansions. Coalescence is described by the Smoluchowski equations, modified to accommodate changes in volume and temperature. The asymptotic form of the cluster size distribution can reveal the scaling of the second-order rate constants K jk with the sizes of colliding particles. Scalings derived in the past are demonstrably incorrect and physically unjustifiable. Here, we use the physically reasonable scaling, K jk = K 11 j μ k μ , to study H 2 coalescence in a nozzle beam. Experimental size distributions fit the predicted asymptotic form, N k = Ak a e −bk , very well, with deviations identifying magic numbers. We obtain the base agglomeration cross section K 11 and the parameter μ, and thus all the rate constants, for H 2 . By comparing with products of geometric cross section and relative velocity, we find sticking coefficients. Experimental results for a nozzle-beam expansion of He are analyzed similarly, to yield K 11 and μ, and hence sticking coefficients, for He. These are compared to those for H 2 .

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“…Another investigation considers the methyl radical to assess the accuracy of the spin-projected unrestricted Hartree-Fock method by investigating electron and spin densities (Glaser & Choy, 1993). Furthermore, reactions with other small molecules like carbon monoxide (Das & Lee, 2014), the recombination reaction with OH radicals (Oliveira & Bauerfeldt, 2012), and even the role in methanol synthesis (Zakharov, Ijagbuji, Tselishtev, Loriya, & Fedotov, 2015) have been studied recently. Due to its high reactivity, the methyl radical is involved in reactions which comprise the abstraction of a hydrogen atom so that many recent studies deal with the kinetic properties of these reactions (Mendes, Zhou, & Curran, 2014), (Saheb, 2015), (Tan, Yang, Krauter, Ju, & Carter, 2015).…”

Section: Single Point Calculationsmentioning

confidence: 99%

Unrestricted Floating Orbitals for the Investigation of Open Shell Systems

Perlt¹,

Apostolidou²,

Eggers³

et al. 2016

IJC

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The floating orbital molecular dynamics approach treats the basis functions' centers in ab initio molecular dynamics simulations variationally optimized in space rather than keeping them strictly fixed on nuclear positions. An implementation of the restricted theory for closed shell systems is already available (Perlt et al., Phys. Chem. Chem. Phys., 2014, 16, 6997-7005). In this article, the extension of the methodology to the unrestricted theory in order to cover open shell systems is introduced. The methyl radical serves as a test system to prove the correctness of the implementation and to demonstrate the scope of this method. The available spin density plots and vibrational spectra are compared to those obtained from atom-centered bases. Finally, more complex systems as well as further properties to be studied in future investigations by floating orbitals are suggested.

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Implementation of a variational code for the calculation of rate constants and application to barrierless dissociation and radical recombination reactions: CH₃OH = CH₃ + OH

Cited by 13 publications

References 54 publications

Quantitative Structure–Property Relationship (QSPR) Models for a Local Quantum Descriptor: Investigation of the 4- and 3-Substituted-Cinnamic Acid Esterification

Quantitative Structure–Property Relationship (QSPR) Models for a Local Quantum Descriptor: Investigation of the 4- and 3-Substituted-Cinnamic Acid Esterification

Rate Constants and Sticking Coefficients for H₂ and He Obtained by Analysis of Agglomeration in a Nozzle Beam

Unrestricted Floating Orbitals for the Investigation of Open Shell Systems

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Implementation of a variational code for the calculation of rate constants and application to barrierless dissociation and radical recombination reactions: CH3OH = CH3 + OH

Cited by 13 publications

References 54 publications

Quantitative Structure–Property Relationship (QSPR) Models for a Local Quantum Descriptor: Investigation of the 4- and 3-Substituted-Cinnamic Acid Esterification

Quantitative Structure–Property Relationship (QSPR) Models for a Local Quantum Descriptor: Investigation of the 4- and 3-Substituted-Cinnamic Acid Esterification

Rate Constants and Sticking Coefficients for H2 and He Obtained by Analysis of Agglomeration in a Nozzle Beam

Unrestricted Floating Orbitals for the Investigation of Open Shell Systems

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Product

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Implementation of a variational code for the calculation of rate constants and application to barrierless dissociation and radical recombination reactions: CH₃OH = CH₃ + OH

Rate Constants and Sticking Coefficients for H₂ and He Obtained by Analysis of Agglomeration in a Nozzle Beam