Single-Sheeted Double Many-Body Expansion Potential Energy Surface for Ground-State ClO<sub>2</sub>

Teixeira, O. B. M.; Mota, V. C.; Vega, José Manuel García de la; Varandas, A. J. C.

doi:10.1021/jp503744x

Cited by 6 publications

(9 citation statements)

References 90 publications

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“…To account for the electronic basis-set incompleteness, we have extrapolated the energies to the complete basis set (CBS) limit using the uniform singlet- and triplet-pair extrapolation (USTE) method, which has been per se or jointly with its generalized version successfully employed in other recent studies of global PESs for a variety of molecular systems. − The extrapolated correlation energy ( E ∞ cor ) is then obtained by fitting to the pair of MRCI+Q/AV T Z and MRCI+Q/AV Q Z calculations for every geometry, thence to the E 3 cor and E 4 cor energies. In the above equation, A 5 (0), c , α, and n are universal parameters, ,− namely, α = −0.375, A 5 (0) = 0.0037685459, c = −1.17847713, and n = 1.25 for the MRCI method.…”

Section: Computational Detailsmentioning

confidence: 99%

Accurate Potential Energy Surface for Quartet State HN₂ and Interplay of N(⁴S) + NH(X̃³Σ^–) versus H + N₂(A³Σ_u⁺) Reactions

et al. 2020

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A global potential energy surface for the lowest quartet state of HN 2 is reported for the first time from accurate multireference ab initio calculations extrapolated to the complete basis set limit using the double many-body expansion method. All its stationary points are characterized, with the lowest quartet of HN 2 predicted to have a bent global minimum 36 kcal mol −1 below the N( 4 S) + NH(X ̃3Σ − ) asymptote, from which it is barrierlessly achievable. The entire set of calculated ab initio points has been fitted for energies up to 1000 kcal mol −1 above the global minimum with an RMSD of 0.89 kcal mol −1 , a gap comprising all identified stationary points. Special care is taken in modeling the involved long-range forces and cusps caused by crossing seams. The novel PES prompts for the calculation of rate constants for several unexplored reactions that are relevant for combustion, plasma, and atmospheric chemistry.

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Section: Computational Detailsmentioning

confidence: 99%

Accurate Potential Energy Surface for Quartet State HN₂ and Interplay of N(⁴S) + NH(X̃³Σ^–) versus H + N₂(A³Σ_u⁺) Reactions

et al. 2020

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“…In turn, the structure located at (β* = 0.0, γ* = 0.784) corresponds to the C 2 v minimum (MC 2 v ), which lies 34 kJ mol –1 above the C s geometry. In fact, the relative position of the C 2 v and C s minima has been the subject of some debate, , with the most recent predictions following the trend displayed by the current DMBE potential energy surface.…”

Section: Potential Energy Surfacementioning

confidence: 99%

Dynamics of the O + ClO Reaction: Reactive and Vibrational Relaxation Processes

et al. 2014

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Classical trajectories have been integrated to study the O + ClO reaction, both reactive and vibrational energy transfer processes, for the range of temperatures 100 ≤ T/K ≤ 500 using momentum Gaussian binning. The employed potential energy surface is the recently proposed single-sheeted double many-body expansion potential energy surface for the (2)A" ground-state of ClO2 based on multireference ab initio data. A capture-type regime with a room-temperature rate constant of (17.8 ± 0.5) × 10(-12) cm(3) s(-1) and temperature dependence of k(T/K)/cm(3) s(-1) = 22.4 × 10(-12) × T(-0.81) exp(-39.2/T) has been found. Although the value reported here is half of the experimental and recommended one, tentative explanations are given. Other dynamical attributes are also examined for the title reaction, with state-to-all and state-to-state vibrational relaxation and excitation rate constants reported for temperatures of relevance in stratospheric chemistry.

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“…The weak bonding and open-shell electronic structure of ClOO result in its notoriously difficult theoretical characterization. A multitude of single reference, − multireference, ,,,− and density functional theory ,− (DFT) studies have been performed on ClOO. For all of these studies, the reported geometries fail to agree with the experimental structure given by Endo and co-workers .…”

Section: Introductionmentioning

confidence: 99%

“…Finally, Varandas and co-workers computed a global ground state potential energy surface (PES) of the ClO 2 system using a double many-body expansion technique based on energies at MRCISD+Q extrapolated to the CBS limit. A detailed topological analysis of the surface was presented, including 10 stationary points, with ClOO as the global minimum.…”

Section: Introductionmentioning

confidence: 99%

“…31 Martin's reported geometry (r e (ClO) = 2.032 Å, r e (OO) = 1.208 Å, and θ e (ClOO) = 115.4°using CCSD(T)/cc-pV(Q +d)Z) is notably different from that determined by Endo. 23 Finally, Varandas and co-workers 29 computed a global ground state potential energy surface (PES) of the ClO 2 system using a double many-body expansion technique based on energies at MRCISD+Q extrapolated to the CBS limit. A detailed topological analysis of the surface was presented, including 10 stationary points, with ClOO as the global minimum.…”

Section: ■ Introductionmentioning

confidence: 99%

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The Structure and Cl–O Dissociation Energy of the ClOO Radical: Finally, the Right Answers for the Right Reason

Abbott

Schaefer

2018

J. Phys. Chem. A

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The chlorine peroxy radical (ClOO) has historically been a highly problematic system for theoretical studies. In particular, the erratic ab initio predictions of the Cl-O bond length reported in the literature thus far exhibit unacceptable errors with respect to the experimental structure. In light of the widespread disagreement observed, we present a careful and systematic investigation of the ClOO geometry toward the basis set and correlation limits of single reference ab initio theory, employing the cc-pVXZ (X = D, T, Q, 5, 6) basis sets extrapolated to the complete basis set limit and coupled cluster theory through single, double, triple, and perturbative quadruple excitations [CCSDT(Q)]. We demonstrate a considerable sensitivity of the Cl-O bond length to both electron correlation and basis set size. The CCSDT(Q)/CBS structure is found to be r(ClO) = 2.082, r(OO) = 1.208, and θ(ClOO) = 115.4°, in remarkable agreement with Endo's semi-experimentally determined values r(ClO) = 2.084(1), r(OO) = 1.206(2), and θ(ClOO) = 115.4(1)°. Moreover, we compute a Cl-O bond dissociation energy of 4.77 kcal mol, which is likewise in excellent agreement with the most recent experimental value of 4.69 ± 0.10 kcal mol.

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Single-Sheeted Double Many-Body Expansion Potential Energy Surface for Ground-State ClO₂

Cited by 6 publications

References 90 publications

Accurate Potential Energy Surface for Quartet State HN₂ and Interplay of N(⁴S) + NH(X̃³Σ^–) versus H + N₂(A³Σ_u⁺) Reactions

Accurate Potential Energy Surface for Quartet State HN₂ and Interplay of N(⁴S) + NH(X̃³Σ^–) versus H + N₂(A³Σ_u⁺) Reactions

Dynamics of the O + ClO Reaction: Reactive and Vibrational Relaxation Processes

The Structure and Cl–O Dissociation Energy of the ClOO Radical: Finally, the Right Answers for the Right Reason

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Single-Sheeted Double Many-Body Expansion Potential Energy Surface for Ground-State ClO2

Cited by 6 publications

References 90 publications

Accurate Potential Energy Surface for Quartet State HN2 and Interplay of N(4S) + NH(X̃3Σ–) versus H + N2(A3Σu+) Reactions

Accurate Potential Energy Surface for Quartet State HN2 and Interplay of N(4S) + NH(X̃3Σ–) versus H + N2(A3Σu+) Reactions

Dynamics of the O + ClO Reaction: Reactive and Vibrational Relaxation Processes

The Structure and Cl–O Dissociation Energy of the ClOO Radical: Finally, the Right Answers for the Right Reason

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Product

Resources

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Single-Sheeted Double Many-Body Expansion Potential Energy Surface for Ground-State ClO₂

Accurate Potential Energy Surface for Quartet State HN₂ and Interplay of N(⁴S) + NH(X̃³Σ^–) versus H + N₂(A³Σ_u⁺) Reactions

Accurate Potential Energy Surface for Quartet State HN₂ and Interplay of N(⁴S) + NH(X̃³Σ^–) versus H + N₂(A³Σ_u⁺) Reactions