V. C. Mota scite author profile

Quasi-classical trajectories have been integrated to study the vibrational relaxation of the O + NO(V) process as a function of the initial vibrational quantum number for T ) 298 K, 1500 K, and 3000 K. Two reliable potential energy surfaces have been employed for the A′ and A′′ doublet states of NO 2 . The calculated vibrational relaxation rate constants show a nearly V-independent behavior at room temperature and a moderate increase with V for higher temperatures. Although deviating significantly from the recommended values, good agreement with recent experimental results has been obtained. The importance of multi-quantum transitions is also analyzed.

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HN₂(²A‘) Electronic Manifold. II. Ab Initio Based Double-Sheeted DMBE Potential Energy Surface via a Global Diabatization Angle

Mota

Varandas

2008

J. Phys. Chem. A

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A double-sheeted double many-body expansion potential energy surface is reported for the coupled 1 2 A′/ 2 2 A′ states of HN 2 by fitting about 6000 ab initio energies. All crossing seams are described to their full extent on the basis of converged results. The lowest adiabatic sheet is fitted with a rmsd of 0.8 kcal mol -1 with respect to the calculated energies up to 100 kcal mol -1 above the absolute minimum, and the topology of the first excited-state investigated with the aid of the upper adiabatic sheet. A new scheme that overcomes obstacles in previous diabatization methods for modeling global double-sheeted potential energy surfaces is also reported. The novel approach uses a global diabatization angle which allows the diabats to mimic both the crossing seams and atom-diatom dissociation limits.

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Ab Initio-Based Global Double Many-Body Expansion Potential Energy Surface for the First²A″ Electronic State of NO₂

2012

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An ab initio-based global double many-body expansion potential energy surface is reported for the first electronic state of the NO(2)((2)A") manifold. Up to 1700 ab initio energies have been employed to map the full configuration space of the title molecule, including stationary points and asymptotic channels. The calculated grid energies have been scaled to account for the incompleteness of the basis set and truncation of the MRCI expansion and fitted analytically with a total root-mean-squared-deviation smaller than 1.0 kcal mol(-1). The lowest point of the potential energy surface corresponds to the (2)B(1) linear minimum, which is separated from the C(s) distorted minimum by a C(2v) barrier of ≈9.7 kcal mol(-1). As usual, the proposed form includes a realistic representation of long-range interactions. Preliminary work indicates its reliability for reaction dynamics.

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The O + NO(v) Vibrational Relaxation Processes Revisited

Caridade

Mota

et al. 2018

J. Phys. Chem. A

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We have carried out a quasiclassical trajectory study of the O + NO( v) energy transfer process using DMBE potential energy surfaces for the ground-states of the A' andA″ manifolds. State-to-state vibrational relaxation rate constants have been computed over the temperature range 298 and 3000 K and initial vibrational states between v = 1 and 9. The momentum-Gaussian binning approach has been employed to calculate the probability of the vibrational transitions. A comparison of the calculated state-to-state rate coefficients with the results from experimental studies and previous theoretical calculations shows the relevance of the 1 A″ potential energy surface to the title vibrational relaxation process.

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HN₂(²A‘) Electronic Manifold. I. A Global ab Initio Study of First Two States

Mota

Varandas

2007

J. Phys. Chem. A

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A detailed ab initio multireference configuration interaction calculation with a standard aug-cc-pVTZ basis set is reported for the 1(2)A' and 2(2)A' states of the title system. The aim is to establish the dissociation scheme of all channels, while revealing the 2(2)A'/3(2)A' seam of conical intersections consistent with the crossings in the diatomic fragments. An ab initio mapping of linear NNH and T-shaped and linear NHN loci of conical intersections is also reported, jointly with a discussion of the topological features associated to a newly reported 2(2)A'/3(2)A' crossing seam.

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V. C. Mota

A Theoretical Study of Rate Coefficients for the O + NO Vibrational Relaxation

HN₂(²A‘) Electronic Manifold. II. Ab Initio Based Double-Sheeted DMBE Potential Energy Surface via a Global Diabatization Angle

Ab Initio-Based Global Double Many-Body Expansion Potential Energy Surface for the First²A″ Electronic State of NO₂

The O + NO(v) Vibrational Relaxation Processes Revisited

HN₂(²A‘) Electronic Manifold. I. A Global ab Initio Study of First Two States

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V. C. Mota

A Theoretical Study of Rate Coefficients for the O + NO Vibrational Relaxation

HN2(2A‘) Electronic Manifold. II. Ab Initio Based Double-Sheeted DMBE Potential Energy Surface via a Global Diabatization Angle

Ab Initio-Based Global Double Many-Body Expansion Potential Energy Surface for the First2A″ Electronic State of NO2

The O + NO(v) Vibrational Relaxation Processes Revisited

HN2(2A‘) Electronic Manifold. I. A Global ab Initio Study of First Two States

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Product

Resources

About

HN₂(²A‘) Electronic Manifold. II. Ab Initio Based Double-Sheeted DMBE Potential Energy Surface via a Global Diabatization Angle

Ab Initio-Based Global Double Many-Body Expansion Potential Energy Surface for the First²A″ Electronic State of NO₂

HN₂(²A‘) Electronic Manifold. I. A Global ab Initio Study of First Two States