Adsorption state of dimethyl disulfide on Au(111): Evidence for adsorption as thiolate at the bridge site

Hayashi, T.; Morikawa, Yoshitada; Nozoye, Hisakazu

doi:10.1063/1.1360245

Cited by 288 publications

(369 citation statements)

References 45 publications

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“…In particular, for Au(111) our minimum energy adsorption geometry is identical to that presented by Hayashi et al 48 and by Maksymovych et al 47 The on top site was found to be the most unfavourable one, followed by the hollow site. In all stepped surfaces, the methyl part is oriented above steps and in all cases in such a way that one of the hydrogen atoms is directed towards the surface, whereas the other two are pointing away from the surface.…”

Section: Au(221) Au(331) and Au(332)supporting

confidence: 63%

“…These results agree with the calculations of Molina and Hammer 8 who found −1.13 eV for (b) and +0.40 eV for (d). For (a), Hayashi et al, 48 report a bridge site adsorption with −0.27 eV per CH 3 S using the PBE exchange-correlation functional. Although the adsorption energy is different, there is good agreement for adsorption geometry.…”

Section: Dissociative Adsorption Of Ch 3 S-sch 3 On Gold Surfacesmentioning

confidence: 99%

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Thiolate adsorption on Au(${\bm {hkl}}$hkl) and equilibrium shape of large thiolate-covered gold nanoparticles

Barmparis

Honkala²,

Remediakis³

2013

The Journal of Chemical Physics

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The adsorption of thiolates on Au surfaces employing density-functional-theory calculations has been studied. The dissociative chemisorption of dimethyl disulfide (CH3S−SCH3) on 14 different Au(hkl) is used as a model system. We discuss trends on adsorption energies, bond lengths, and bond angles as the surface structure changes, considering every possible Au(hkl) with h, k, l ⩽ 3 plus the kinked Au(421). Methanethiolate (CH3S-) prefers adsorption on bridge sites on all surfaces considered; hollow and on top sites are highly unfavourable. The interface tensions for Au(hkl)-thiolate interfaces is determined at low coverage. Using the interface tensions in a Wulff construction method, we construct atomistic models for the equilibrium shape of large thiolate-covered gold nanoparticles. Gold atoms in a nanoparticle change their equilibrium positions upon adsorption of thiolates towards shapes of higher sphericity and higher concentration of step-edge atoms.

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Section: Au(221) Au(331) and Au(332)supporting

confidence: 63%

Section: Dissociative Adsorption Of Ch 3 S-sch 3 On Gold Surfacesmentioning

confidence: 99%

Thiolate adsorption on Au(${\bm {hkl}}$hkl) and equilibrium shape of large thiolate-covered gold nanoparticles

Barmparis

Honkala²,

Remediakis³

2013

The Journal of Chemical Physics

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“…Calculations were carried out by using the first-principles molecular dynamics program ''STATE'' (Simulation Tool for Atom TEchnology) which has been applied to organic/ metal interfaces [23][24][25][26]. We employed the local density approximation (LDA) [27,28] and the generalized gradient approximation (GGA) [29] for the exchange-correlation energy functional.…”

Section: Methodsmentioning

confidence: 99%

First-principles molecular dynamics study of Al/Alq₃interfaces

Takeuchi

Yanagisawa

Morikawa

2007

Science and Technology of Advanced Materials

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We have carried out first-principles molecular dynamics simulations of Al deposition on tris (8-hydroxyquinoline) aluminum ðAlq 3 Þ layers to investigate atomic geometries and electronic properties of Al=Alq 3 interfaces. Al atoms were ejected to Alq 3 one by one with the kinetic energy of 37.4 kJ/mol, which approximately corresponds to the average kinetic energy of Al at the boiling temperature of metal Al. The first Al atom interacts with two of the three O atoms of meridional Alq 3 . Following Al atoms interact with Alq 3 rather weakly and they tend to aggregate each other to form Al clusters. During the deposition process, Alq 3 was not broken and its molecular structure remained essentially intact. At the interface, weak bonds between deposited Al atoms and N and C atoms were formed. The projected density of states (PDOS) onto the Alq 3 molecular orbitals shows gap states in between the highest occupied molecular orbitals (HOMOs) and the lowest unoccupied molecular orbitals (LUMOs), which were experimentally observed by ultraviolet photoelectron spectroscopy (UPS) and metastable atom electron spectroscopy (MAES). Our results show that even though the Alq 3 molecular structure is retained, weak N-Al and C-Al bonds induce gap states. r

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“…We used the Kohn-Sham method in the generalized gradient approximation for the electronic structure calculation, with numerical atomic orbitals (double zeta plus polarization) The initial and relaxed site, the adsorption energy with respect to the fcc-bridge case, the height of the sulfur atom from the gold surface, the average of the three nearest neighbor Au-S distances, and the S-C bond length and angle θ to the surface normal. (81 k-points are used, yielding a converged adsorption energy [20].) as the basis set, by means of the SIESTA program [18].…”

mentioning

confidence: 99%

Intermolecular effect in molecular electronics

Baranger

et al. 2005

The Journal of Chemical Physics

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We investigate the effects of lateral interactions on the conductance of two molecules connected in parallel to semi-infinite leads. The method we use combines a Green function approach to quantum transport with density functional theory for the electronic properties. The system, modeled after a self-assembled monolayer, consists of benzylmercaptane molecules sandwiched between gold electrodes. We find that the conductance increases when intermolecular interaction comes into play. The source of this increase is the indirect interaction through the gold substrate rather than direct molecule-molecule interaction. A striking resonance is produced only 0.3 eV above the Fermi energy.

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Adsorption state of dimethyl disulfide on Au(111): Evidence for adsorption as thiolate at the bridge site

Cited by 288 publications

References 45 publications

Thiolate adsorption on Au(${\bm {hkl}}$hkl) and equilibrium shape of large thiolate-covered gold nanoparticles

Thiolate adsorption on Au(${\bm {hkl}}$hkl) and equilibrium shape of large thiolate-covered gold nanoparticles

First-principles molecular dynamics study of Al/Alq₃interfaces

Intermolecular effect in molecular electronics

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Adsorption state of dimethyl disulfide on Au(111): Evidence for adsorption as thiolate at the bridge site

Cited by 288 publications

References 45 publications

Thiolate adsorption on Au(${\bm {hkl}}$hkl) and equilibrium shape of large thiolate-covered gold nanoparticles

Thiolate adsorption on Au(${\bm {hkl}}$hkl) and equilibrium shape of large thiolate-covered gold nanoparticles

First-principles molecular dynamics study of Al/Alq3interfaces

Intermolecular effect in molecular electronics

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First-principles molecular dynamics study of Al/Alq₃interfaces