Ab Initio Adiabatic Potential Energy Surfaces and Non-adiabatic Couplings for O3: Construction of Four State Diabatic Hamiltonian
Abstract
We compute highly accurate first principle based ab initio adiabatic potential energy surfaces (PESs) using State-Averaged Multi-Configurational Self-Consistent Field (SA-MCSCF) followed by internally contracted Multi-Reference Configuration Interaction method incorporating fixed-reference Davidson corrections [ic-MRCI(Q)], where a full valence active space of 18 electrons in 12 orbitals and aug-cc-pVQZ basis set are employed for the low-lying four singlet electronic states of ozone (X1A', 1~1A'', 1~1A' and 21A''). It accurately reproduces the dissociation energies of ozone (1.101 eV) as well as the molecular oxygen (5.106 eV) along with vibrational frequencies of O3 in comparison with experimental data. To ensure appropriate accuracy and proper convergence in the interaction as well as asymptotic regions, we (a) extend the number of electronic states in SA-MCSCF calculation (singlet as well as triplet and quintet); (b) systematically expand the active space [(12e,9o) → (18e,12o) → (24e,15o)] and basis set size (AVDZ → AV6Z → Complete Basis Set limit); (c) incorporate multi-reference character along with Davidson correction. Conical intersections between the adjacent electronic states (1-2, 2-3 and 3-4) are located at C2v, D3h as well as Cs geometries through the four-state adiabatic-to-diabatic transformation of non-adiabatic coupling terms (NACTs) computed at Coupled-Perturbed Multi-Configurational Self-Consistent Field (CP-MCSCF) method along the circular contours. Finally, we present: (a) ic-MRCI(Q) calculated minimum energy path of incoming oxygen to the diatom (O2) is devoid of any ``reef'' feature; (b) NACTs and diabatic PES matrix elements as function of hyperangles (θ,φ) at a fixed hyperradius = 4 Bohr for a four state sub-Hilbert space.
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