Charge Redistribution Effects on the UV–Vis Spectra of Small Ligated Gold Clusters: a Computational Study

Lugo, G.; Schwanen, Valérie; Fresch, Barbara; Remacle, Françoise

doi:10.1021/jp511120j

Cited by 35 publications

(51 citation statements)

References 50 publications

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“…However, the charge on these clusters, Au 25 (SR) 18 and Ag 25 (SR) 18 , is not localized but dispersed over atoms in their core, staples and ligands2329. Hence, the two clusters may not experience considerable repulsive interactions between them when they approach each other.…”

Section: Resultsmentioning

confidence: 99%

Structure-conserving spontaneous transformations between nanoparticles

Krishnadas¹,

Baksi²,

Ghosh³

et al. 2016

Nat Commun

112

186

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Ambient, structure- and topology-preserving chemical reactions between two archetypal nanoparticles, Ag25(SR)18 and Au25(SR)18, are presented. Despite their geometric robustness and electronic stability, reactions between them in solution produce alloys, AgmAun(SR)18 (m+n=25), keeping their M25(SR)18 composition, structure and topology intact. We demonstrate that a mixture of Ag25(SR)18 and Au25(SR)18 can be transformed to any arbitrary alloy composition, AgmAun(SR)18 (n=1–24), merely by controlling the reactant compositions. We capture one of the earliest events of the process, namely the formation of the dianionic adduct, (Ag25Au25(SR)36)2−, by electrospray ionization mass spectrometry. Molecular docking simulations and density functional theory (DFT) calculations also suggest that metal atom exchanges occur through the formation of an adduct between the two clusters. DFT calculations further confirm that metal atom exchanges are thermodynamically feasible. Such isomorphous transformations between nanoparticles imply that microscopic pieces of matter can be transformed completely to chemically different entities, preserving their structures, at least in the nanometric regime.

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Section: Resultsmentioning

confidence: 99%

Structure-conserving spontaneous transformations between nanoparticles

Krishnadas¹,

Baksi²,

Ghosh³

et al. 2016

Nat Commun

112

186

View full text Add to dashboard Cite

show abstract

“…[17] However,t he need for atomically precise syntheses or separation methods limits the surface chemistries that can be explored, and experimental methods sensitive to electronic structure typically do not provide the necessary detail to identify trends or benchmark quantum chemical studies. [14,18,19] Thec ombination of anisotropic solvent environments,t hermal averaging, impurities,a nd ligand dissociation or core isomerization obfuscate quantitative comparisons between species or with quantum chemical predictions,h ampering efforts to develop ac ohesive framework to rationalize electronic structure and necessitating anew approach. [8,14,[20][21][22] In order to overcome such challenges,w et urned to cryogenic ion trap photofragmentation spectroscopy,ameasurement which combines the selectivity of mass-spectrometry with the spectral detail of low-temperature UV/Vis spectroscopy to provide ap robe of electronic structure approaching the physical limit of spectroscopic resolving power.…”

Section: Systematically Tuning the Electronic Structure Of Gold Nanocmentioning

confidence: 99%

Systematically Tuning the Electronic Structure of Gold Nanoclusters through Ligand Derivatization

et al. 2019

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While the ability to crystallizemetal nanoclusters has revealed their geometric structure,t he lacko fasimilarly precise measure of their electronic structure has hampered the development of synthetic design rules to precisely engineer their electronic properties.W et rackt he evolution of highlyresolved electronic absorption spectra of gold nanoclusters with precisely mass-selected chemical composition in ac ontrolled environment. Simple derivatization of the ligands yields larger spectral changes than varying the overall atomic composition of the cluster for two clusters with similar symmetry and size.T he nominally metal-localized HOMO-LUMO transition of these nanoclusters lowers in energy linearly with increasing electron donation from the exterior of the ligand shell for both cluster sizes.V ery weak surface interactions,such as binding of He or N 2 ,yield significant statedependent shifts,i dentifying states with significant interfacial character.T hese observations demonstrate ap athway for deliberate tuning of interfacial chemistry for chemical and technological applications.

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“…Pohjolainen et al found that changing the ligand anchor atom had a pronounced effect on optical spectra . Lugo et al found by changing the chemistry of the ligand on different sized AuNCs that the more negative the partial charge on the core, the more the lowest absorption band was shifted to the red …”

Section: Electronic Structure Calculationsmentioning

confidence: 99%

“…[ 74 ] Lugo et al found by changing the chemistry of the ligand on different sized AuNCs that the more negative the partial charge on the core, the more the lowest absorption band was shifted to the red. [ 75 ] While TDDFT is an exceptional method for examining the optical properties of NPs, it is not the only useful technique to do so. Tlahuice-Flores et al found that far-IR and low-frequency Raman can be used to fi ngerprint AuNCs using standard DFT methods for calculating IR spectra.…”

Section: Optical and Electronic Propertiesmentioning

confidence: 99%

Understanding and Designing the Gold–Bio Interface: Insights from Simulations

Charchar

Christofferson

Todorova

et al. 2016

Small

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Gold nanoparticles (AuNPs) are an integral part of many exciting and novel biomedical applications, sparking the urgent need for a thorough understanding of the physicochemical interactions occurring between these inorganic materials, their functional layers, and the biological species they interact with. Computational approaches are instrumental in providing the necessary molecular insight into the structural and dynamic behavior of the Au-bio interface with spatial and temporal resolutions not yet achievable in the laboratory, and are able to facilitate a rational approach to AuNP design for specific applications. A perspective of the current successes and challenges associated with the multiscale computational treatment of Au-bio interfacial systems, from electronic structure calculations to force field methods, is provided to illustrate the links between different approaches and their relationship to experiment and applications.

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Charge Redistribution Effects on the UV–Vis Spectra of Small Ligated Gold Clusters: a Computational Study

Cited by 35 publications

References 50 publications

Structure-conserving spontaneous transformations between nanoparticles

Structure-conserving spontaneous transformations between nanoparticles

Systematically Tuning the Electronic Structure of Gold Nanoclusters through Ligand Derivatization

Understanding and Designing the Gold–Bio Interface: Insights from Simulations

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