Spin polarized density functional theory calculation combined with periodic slabs were employed to reveal the elemental mercury (Hg-0) adsorption mechanism on Co3O4 (110) surface. The adsorption energies and possible adsorption sites were investigated. To understand the adsorption interaction more directly, the electronic structural changes of before and after adsorption were compared. The hybridization of orbitals was studied by the partial density of states (PDOS) analysis. In addition, the temperature effects toward equilibrium constants of Hg-0-Co3O4 system were taken into consideration. The results manifested that the interaction between Hg-0 and Co3O4 (11 0) surface is chemisorption with -74.037 klimol. Co3+ sites, the highest oxidation state of Co atoms, are crucial in this process which can accept the electrons after Hg-0 oxidation. The redundant electrons transfer to 0 and other Co atoms nearby. PDOS analysis indicates the hybridization of s orbitals (Hg-0) and p, d orbitals (Co atom). And d orbitals of Hg-0 interacts with s, p orbitals of Co atom strongly. The trends of equilibrium constants suggest that Hg-0 adsorption on Co3O4 (1 1 0) surface is favorable at low temperature. (C) 2016 Elsevier B.V. All rights reserved.