Gold surfaces and nanoparticles are protected by Au(0)–thiyl species and are destroyed when Au(I)–thiolates form

Abstract: The synthetic chemistry and spectroscopy of sulfur-protected gold surfaces and nanoparticles is analyzed, indicating that the electronic structure of the interface is Au(0)-thiyl, with Au(I)-thiolates identified as high-energy excited surface states. Density-functional theory indicates that it is the noble character of gold and nanoparticle surfaces that destabilizes Au(I)-thiolates. Bonding results from large van der Waals forces, influenced by covalent bonding induced through s-d hybridization and charge pol… Show more

“…[395] Many properties of the two head-group arrangements are very similar despite the significant change in coordination, suggesting that the binding mechanism is similar in both cases. Also the binding strengths of the chemisorbed forms are not that much greater than those of the physisorbed forms [382,396] and are consistent with the binding of nitrogen and phosphorous bases to the surface, processes known to be controlled by the dispersion interaction. The postulate that both the 'physisorption' and 'chemisorption' processes depicted in the above reactions involve primarily dispersion forces and the Au 0 -thiyl valence state provides a consistent analysis of all of these data, including that for other chemical variations such as the replacement of Au with Ag or Cu and the replacement of S with O, Se, or Te.…”

“…While such ideas have always been recognized in Pearson's concept of hard/soft acids and bases, [378][379][380][381] that the dispersion force can be large enough to compete with covalent and ionic binding is just coming to be understood. [382,383] [383] and that Au 0 -thiyls are the species that actually protect gold surfaces and nanoparticles while Au I -thiolate production etches surfaces and inhibits nanoparticle formation. [382] The competition between covalent/ionic and van der Waals bonding is critical in each case, and Pearson's ideas predict the main results as S and Au are soft while Fe can be either hard or soft.…”

“…[382,383] [383] and that Au 0 -thiyls are the species that actually protect gold surfaces and nanoparticles while Au I -thiolate production etches surfaces and inhibits nanoparticle formation. [382] The competition between covalent/ionic and van der Waals bonding is critical in each case, and Pearson's ideas predict the main results as S and Au are soft while Fe can be either hard or soft. The Au-Au bond has always been regarded as anomalous, with the concept of 'aurophilicity' used to describe it, [384,385] but this is now known to be just the strong dispersion force acting on top of strong s-s interactions that make the gold atoms in a gold dimer more like those in gold metal than like isolated gold atoms.…”

“…[386,387] Understanding whether or not processes occur on the Au 0 -thiyl or Au I -thiolate potential-energy surfaces is essential to rationalizing the known synthetic chemistry and spectroscopy of gold surfaces and nanoparticles. [382] Work with Noel Hush (Sydney University) and Jens Ulstrup and Jingdong Zhang (Danish Technical University) has shown that gold (111) surfaces react with thiol or disulfide reagents to form initially 'physisorbed' species and then 'chemisorbed' ones (Scheme 1):…”

“…The postulate that both the 'physisorption' and 'chemisorption' processes depicted in the above reactions involve primarily dispersion forces and the Au 0 -thiyl valence state provides a consistent analysis of all of these data, including that for other chemical variations such as the replacement of Au with Ag or Cu and the replacement of S with O, Se, or Te. [382] However, gold does not react with solutions containing thiolate anions RS À , but in an electrochemical cell in which Au I is produced at the anode and RS À at the cathode, the two species combine in solution to form Au I -thiolate compounds and thin films that then precipitate onto the surface (Scheme 2). [397] Au I and thiolate ions are present as intermediates and their reaction produces an end product completely different to the protected SAM-covered surface produced by reactions with thiols and disulfides.…”

Putting David Craig’s Legacy to Work in Nanotechnology and Biotechnology

“…[395] Many properties of the two head-group arrangements are very similar despite the significant change in coordination, suggesting that the binding mechanism is similar in both cases. Also the binding strengths of the chemisorbed forms are not that much greater than those of the physisorbed forms [382,396] and are consistent with the binding of nitrogen and phosphorous bases to the surface, processes known to be controlled by the dispersion interaction. The postulate that both the 'physisorption' and 'chemisorption' processes depicted in the above reactions involve primarily dispersion forces and the Au 0 -thiyl valence state provides a consistent analysis of all of these data, including that for other chemical variations such as the replacement of Au with Ag or Cu and the replacement of S with O, Se, or Te.…”

“…While such ideas have always been recognized in Pearson's concept of hard/soft acids and bases, [378][379][380][381] that the dispersion force can be large enough to compete with covalent and ionic binding is just coming to be understood. [382,383] [383] and that Au 0 -thiyls are the species that actually protect gold surfaces and nanoparticles while Au I -thiolate production etches surfaces and inhibits nanoparticle formation. [382] The competition between covalent/ionic and van der Waals bonding is critical in each case, and Pearson's ideas predict the main results as S and Au are soft while Fe can be either hard or soft.…”

“…[382,383] [383] and that Au 0 -thiyls are the species that actually protect gold surfaces and nanoparticles while Au I -thiolate production etches surfaces and inhibits nanoparticle formation. [382] The competition between covalent/ionic and van der Waals bonding is critical in each case, and Pearson's ideas predict the main results as S and Au are soft while Fe can be either hard or soft. The Au-Au bond has always been regarded as anomalous, with the concept of 'aurophilicity' used to describe it, [384,385] but this is now known to be just the strong dispersion force acting on top of strong s-s interactions that make the gold atoms in a gold dimer more like those in gold metal than like isolated gold atoms.…”

“…[386,387] Understanding whether or not processes occur on the Au 0 -thiyl or Au I -thiolate potential-energy surfaces is essential to rationalizing the known synthetic chemistry and spectroscopy of gold surfaces and nanoparticles. [382] Work with Noel Hush (Sydney University) and Jens Ulstrup and Jingdong Zhang (Danish Technical University) has shown that gold (111) surfaces react with thiol or disulfide reagents to form initially 'physisorbed' species and then 'chemisorbed' ones (Scheme 1):…”

“…The postulate that both the 'physisorption' and 'chemisorption' processes depicted in the above reactions involve primarily dispersion forces and the Au 0 -thiyl valence state provides a consistent analysis of all of these data, including that for other chemical variations such as the replacement of Au with Ag or Cu and the replacement of S with O, Se, or Te. [382] However, gold does not react with solutions containing thiolate anions RS À , but in an electrochemical cell in which Au I is produced at the anode and RS À at the cathode, the two species combine in solution to form Au I -thiolate compounds and thin films that then precipitate onto the surface (Scheme 2). [397] Au I and thiolate ions are present as intermediates and their reaction produces an end product completely different to the protected SAM-covered surface produced by reactions with thiols and disulfides.…”

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