Your search keyword '"Machado, Francisco B.C."' showing total 2 results

1. Electronic structure and stability of transition metal acetylacetonates TM(AcAc)n (TM = Cr, Fe, Co, Ni, Cu; n = 1, 2, 3).

Author

Fernandes, Gabriel F.S., Pontes, Marcelo A.P., Machado, Francisco B.C., and Ferrão, Luiz F.A.

Subjects

ELECTRONIC structure, LIGAND field theory, TRANSITION metals, POLYMERS, TRANSITION metal catalysts, POLYMERIZATION

Abstract

[Display omitted] • Low-lying electronic states of the TM(AcAc) 1-3 (TM = Cr, Fe, Co, Ni, Cu) molecules. • Ligand field theory and CASPT2 electronic structure description. • Cu(AcAc) 1 , Ni(AcAc) 2, and Co(AcAc) 3 molecules present as stability peaks. • Quantitative stability description by the ε3 stability ranking function. Transition metal acetylacetonates have a wide range of technological applications, such as modifiers in polymers and polymerization catalysts. Since the electronic structure defines the physical-chemistry properties of these materials and ultimately their selectivity in technological applications, its characterization is of paramount importance. In this work, the general trends on the electronic structure of the transition metal acetylacetonate TM(AcAc) were estimated from qualitative and quantitative approaches. The qualitative picture, based on the ligand field theory, allowed to establish a relation between the d-orbital electron occupancy and the stability of the system, in which the Cu(AcAc) 2 presents a limitrophe case, indicating moderate stability and reactivity. On the quantitative approach, the low-lying electronic states of TM(AcAc) were characterized by highly correlated methods. The thermodynamic and kinetic stabilities of TM(AcAc) n were ranked by using a stability index based on parameters of the wavefunction, namely, the excitation energy, the free energy of atomization, and the HOMO energy, showing a good agreement with the qualitative results. Besides the spectroscopic data provided for TM(AcAc) n , the combined qualitative and quantitative results can guide the choice of a specific TM(AcAc) n in applications that require higher or lower stabilities. [ABSTRACT FROM AUTHOR]

Published

2022

2. A theoretical characterization of the ground state of LiC, LiC+and LiC−

Author

Machado, Francisco B.C., Bravo, Ricardo, and Roberto-Neto, Orlando

Abstract

Potential energy curves, dipole moment functions and spectroscopic constants for the ground state of LiC, LiC+and LiC−are reported using a multireference configuration interaction approach. The core–valence correlation effects in the properties were also investigated. For the first time, the adiabatic ionization potential and the electronic affinity of LiC were calculated including core–valence effects and found to be 7.73 and 0.23eV, respectively.

Published

1999