Cluster and periodic DFT calculations of adsorption of hydroxyl on the Au(hkl) surfaces

“…The bridge site is more stable than top site on every surface. The most stable structures on Au(211) edge bridge sites in Figures h (−2.39 eV) and 2i (−2.38 eV) are according to the calculated results (−2.42 eV) of (111)‐(100) edge bridge site on Au(321) step surface by Pessoa et al The stability order of OH adsorption on the slab surfaces is (111)‐(100) edge bridge in Au(211) > Au(100) bridge > (111)‐(100) edge top in Au(211) > Au(100) top > Au(111) bridge > Au(111) top sites. Pessoa et al also reported the similar OH stability order, that is, (321) > (100) > (111).…”

“…Pessoa et al analyzed the OH adsorption on Au(111), (110), (100), and (321) slab surfaces assuming that the adsorbed OH may act as catalytic promoter or adsorption preference on gold surface. However, the OH was formed by reorganization of electronic structure after adsorption of OH − in alkaline solution.…”

First-principles calculation of OH⁻/OH adsorption on gold nanoparticles

“…The bridge site is more stable than top site on every surface. The most stable structures on Au(211) edge bridge sites in Figures h (−2.39 eV) and 2i (−2.38 eV) are according to the calculated results (−2.42 eV) of (111)‐(100) edge bridge site on Au(321) step surface by Pessoa et al The stability order of OH adsorption on the slab surfaces is (111)‐(100) edge bridge in Au(211) > Au(100) bridge > (111)‐(100) edge top in Au(211) > Au(100) top > Au(111) bridge > Au(111) top sites. Pessoa et al also reported the similar OH stability order, that is, (321) > (100) > (111).…”

“…Pessoa et al analyzed the OH adsorption on Au(111), (110), (100), and (321) slab surfaces assuming that the adsorbed OH may act as catalytic promoter or adsorption preference on gold surface. However, the OH was formed by reorganization of electronic structure after adsorption of OH − in alkaline solution.…”

First-principles calculation of OH⁻/OH adsorption on gold nanoparticles

“…structure is the thermodynamically more stable one [34]. The theoretical calculations also showed that in both cases, the SAM molecules preferably adsorb at Au bridge sites which is also the preferred adsorption site of OH [35,36]. Moreover, due to the tilt of the 4-mercaptopyridine molecules, adjacent adsorption sites are sterically blocked [34].…”

Hydrogen Peroxide Oxidation Reaction on a 4-Mercaptopyridine Self-Assembled Monolayer on Au(111) Metallized by Platinum Nanoislands

“…21,50,[60][61][62][63][64][65][66] The (111) and (110) slab models used in this work consist of 2 × 2 unit cells with respect to the minimal unit cell and have a thickness of four metallic layers. 73 The convergence of the results with the number of atomic layers in the slab was checked in previous works. 71,73 Some gold atoms in the topmost layer of these surfaces were substituted by atoms of Rh or of Ir, or also by atoms of Ni (a cheap metal) or of Ag which is usually used for the elaboration of catalysts for the NO x elimination.…”

“…73 The convergence of the results with the number of atomic layers in the slab was checked in previous works. 71,73 Some gold atoms in the topmost layer of these surfaces were substituted by atoms of Rh or of Ir, or also by atoms of Ni (a cheap metal) or of Ag which is usually used for the elaboration of catalysts for the NO x elimination. [27][28][29][30] In the case of the Au(110) surface, only Au atoms at the ridges (from now on named combs as in Ref.…”

A DFT study of the NO dissociation on gold surfaces doped with transition metals