Theoretical Prediction of S–H Bond Rupture in Methanethiol upon Interaction with Gold

Askerka, Mikhail; Пичугина, Д. А.; Кузьменко, Н.Е.; Shestakov, Alexander F.

doi:10.1021/jp303001x

Cited by 32 publications

(40 citation statements)

References 51 publications

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“…Previous theoretical investigations predicted that the RS-Au-SR staple motif were formed from the co-adsorption of two CH 3 SH molecules on metal atom. 20 − products simultaneously present in the Au − + CH 3 SH reaction (Fig. S1 of the supplementary material), 51 supporting this formation mechanism.…”

Section: Discussionmentioning

confidence: 55%

“…Experimentally, the loss of hydrogen has been observed upon the exposure of thiols to very large gold particles (∼4 nm, about Au 2000 size). 19 Theoretical investigations have suggested a most likely pathway of S-H bond rupture of the CH 3 SH molecule on the Au atom and Au 20 , 20 surfaces, 22 namely, the co-adsorption of two or three CH 3 SH molecules on the gold clusters induce the release of H 2 and the formation of the staple motif. Recent photoelectron spectroscopic and theoretical investigation reveals a covalent characteristic of the Au-S bond.…”

Section: Introductionmentioning

confidence: 99%

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Photoelectron velocity-map imaging spectroscopic and theoretical study on the reactivity of the gold atom toward CH3SH, CH3OH, and H2O

Qin

Cong

et al. 2013

The Journal of Chemical Physics

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Photoelectron velocity-map imaging spectroscopy has been used to study the reaction of the anionic gold atom with the HR (R = SCH 3 , OCH 3 , OH) molecules. The solvated [Au· · ·HR] − and inserted [HAuR] − products have been experimentally observed for R = SCH 3 , whereas only solvated [Au· · ·HR] − products were found for R = OCH 3 and OH. This significant difference in the photoelectron spectra suggests the different reactivity of the Au − toward the CH 3 SH, CH 3 OH, and H 2 O molecules. Second order Møller-Plesset perturbation theory and coupled-cluster single double triple excitation calculations have been performed to aid the structural assignment of the spectra and to explore the reaction mechanism. Activation energies for the isomerizations of the solvated structures to the inserted ones in the Au − /Au + HR reactions (R = OCH 3 and OH) are predicted to be much higher than those for the Au − /Au + CH 3 SH reactions, supporting the experimental observation. Theoretical calculations provide the evidence that the intriguing [HAuSCH 3 ] − product may be formed by the attachment of the electron onto the neutral HAuSCH 3 species or the isomerization from the anionic [Au· · ·HSCH 3 ]− one. These findings should be helpful for understanding the feature that the thiols are able to form the staple motifs, whereas CH 3 OH and H 2 O are not. © 2013 AIP Publishing LLC. [http://dx

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Section: Discussionmentioning

confidence: 55%

Section: Introductionmentioning

confidence: 99%

Photoelectron velocity-map imaging spectroscopic and theoretical study on the reactivity of the gold atom toward CH3SH, CH3OH, and H2O

Qin

Cong

et al. 2013

The Journal of Chemical Physics

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“…A several-functional compilation for AuCO 30 provides binding energies from 1/3 (M06-2X 31 ) to 3/2 (PBE0) to over twofold overbinding by the favorites of the gold community: BP86, 32, 33 PBE, 34 and PW91. 35 A similar, albeit narrower, comparison for Au-methylthiol 36 shows twofold disparity between PW91 (PBE) and B3LYP. 37 Arguably, with such uncertainty on every rung of DFT, the structural and energetical predictions of ligand protected gold nanoparticles could vary from functional to functional.…”

Section: Introductionmentioning

confidence: 83%

“…The latter issue has been extensively discussed in the literature. 36,45,47,46,82 A less convoluted explanation takes into account that electrons tend to flow from a region of high chemical potential (low electronegativity) to a region of low chemical potential (high electronegativity). Both of these quantities are well defined within DFT.…”

Section: Interaction Energies Of Organo-sulfur Ligandsmentioning

confidence: 99%

Density functional theory approach to gold-ligand interactions: Separating true effects from artifacts

Koppen

Hapka

Modrzejewski

et al. 2014

The Journal of Chemical Physics

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Donor-acceptor interactions are notoriously difficult and unpredictable for conventional density functional theory (DFT) methodologies. This work presents a reliable computational treatment of gold-ligand interactions of the donor-acceptor type within DFT. These interactions require a proper account of the ionization potential of the electron donor and electron affinity of the electron acceptor. This is accomplished in the Generalized Kohn Sham framework that allows one to relate these properties to the frontier orbitals in DFT via the tuning of range-separated functionals. A donor and an acceptor typically require different tuning schemes. This poses a problem when the binding energies are calculated using the supermolecular method. A two-parameter tuning for the monomer properties ensures that a common functional, optimal for both the donor and the acceptor, is found. A reliable DFT approach for these interactions also takes into account the dispersion contribution. The approach is validated using the water dimer and the (HAuPH3)2 aurophilic complex. Binding energies are computed for Au4 interacting with the following ligands: SCN(-), benzenethiol, benzenethiolate anion, pyridine, and trimethylphosphine. The results agree for the right reasons with coupled-cluster reference values.

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“…[26,27] For both H 2 S and SO 2 adsorption on small gold clusters (which are planar), the sulfur atom is in the same plane and these molecules preferentially adsorb at a single low-coordination gold atom on the gold cluster. [28][29][30][31][32][33] Although impressive progress has been achieved in understanding the adsorption of small molecules on small gold clusters, computational studies for large gold clusters are generally lacking. A notable exception is the study of Gao et al [34] which examined the adsorption of CO on free subnanometer gold clusters (Au 16 -Au 18 , Au 20 , and Au 27 -Au 35 ).…”

Section: Previous Calculations For Adsorption Of Small Molecules On Gmentioning

confidence: 99%

Adsorption of small molecules on helical gold nanorods: A relativistic density functional study

Liu

Hamilton

2014

J. Comput. Chem.

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We study the adsorption of a variety of small molecules on helical gold nanorods using relativistic density functional theory. We focus on Au40 which consists of a central linear strand of five gold atoms with seven helical strands of five gold atoms on a coaxial tube. All molecules preferentially adsorb at a single low-coordinated gold atom on the coaxial tube at an end of Au40. In most cases, there is significant charge transfer (CT) between Au40 and the adsorbate, for CO and NO2, there is CT from the Au40 to adsorbate while for all other molecules there is CT from the adsorbate to Au40. Thus, Au40-adsorbate can be described as a donor-accepter complex and we use charge decomposition analysis to better understand the adsorption process. We determine the adsorption energy order to be C5H5N >NO2 > CO > NH3 > CH2=CH2 > CH2=CH-CHO > NO > HC≡CH > H2S > SO2 > HCN > CH3OH > H2C=O > O2 > H2O > CH4 > N2. We find that the Au-C, Au-N, Au-S, and Au-O bonds are surprisingly strong, with clear implications for reactivity enhancement of the adsorbate. The Au-H bond is relatively weak but, for interactions via an H atom that is bonded to a carbon atom (e.g., CH4), we find that there is large charge polarization of the Au-H-C moiety and partial activation of the inert C-H bond. Although the Au-S and Au-O bonds are generally weaker than the Au-C and Au-N bonds, we find that adsorption of H2S or H2O causes greater distortion of Au40 in the binding region. However, the degree of distortion is small and the helical structure is retained, demonstrating the stability of the helical Au40 nanorod under perturbations.

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Theoretical Prediction of S–H Bond Rupture in Methanethiol upon Interaction with Gold

Cited by 32 publications

References 51 publications

Photoelectron velocity-map imaging spectroscopic and theoretical study on the reactivity of the gold atom toward CH3SH, CH3OH, and H2O

Photoelectron velocity-map imaging spectroscopic and theoretical study on the reactivity of the gold atom toward CH3SH, CH3OH, and H2O

Density functional theory approach to gold-ligand interactions: Separating true effects from artifacts

Adsorption of small molecules on helical gold nanorods: A relativistic density functional study

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