The Electrophilicity index (𝜔) is related to the energy lowering associated with the maximum amount of electron flow between a donor and an acceptor and possesses adequate information regarding structure, stability, reactivity, and interactions. Chemical potential (μ) measures charge transfer from a system to another having a lower value of μ, while chemical hardness (η) is a measure of the characterized relative stability of clusters. The main purpose of the present research work is to examine the Spin-Orbit Coupling (SOC) effect on the behavior of the electrophilicity index, chemical potential, hardness and softness of neutral gold clusters Au_n (n=2-6). Using the second-order Douglas-Kroll-Hess Hamiltonian, geometries are optimized at the DKH2-B3P86/DZP-DKH level of theory. Spin-orbit coupling energies are computed using the fourth-order Douglas-Kroll-Hess Hamiltonian, generalized Hartree-Fock method and all-electron relativistic double-ζ level basis set. Then, spin-orbit coupling (SOC) corrections to the electrophilicity index, chemical potential, hardness and softness are calculated. It is revealed that spin-orbit correction to the vertical chemical hardness has an important effect on Au₃ and Au₆, i.e. SOC decreases (increases) the hardness of gold trimer (hexamer). Due to the relationship between hardness and softness, σ =1/η, inclusion of spin-orbit coupling increases (decreases) the softness of Au₃ (Au₆) and thus destabilizes (stabilizes) it. Spin-orbit coupling (SOC) also has an important effect on the chemical potential of Au₃ by decreasing its value. It is found that spin-orbit coupling has a considerable effect on the electrophilicity index of gold trimer and greatly increases its value. Furthermore, SOC increases the maximal charge acceptance of Au₃ more and thus destabilizes it more. As a result, the spin-orbit coupling effect appears to be important in calculating the electrophilicity index of the gold trimer.

Doi: 10.28991/HIJ-2021-02-01-05

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