The van der Waals Interactions of n‐Alkanethiol‐Covered Surfaces: From Planar to Curved Surfaces

Cometto, Fernando P.; Luo, Zhi; Zhao, Suping; Olmos-Asar, Jimena A.; Mariscal, Marcelo M.; Ong, Quy K.; Kern, Klaus; Stellacci, Francesco; Lingenfelder, Magalí

doi:10.1002/anie.201708735

Cited by 12 publications

(18 citation statements)

References 33 publications

(52 reference statements)

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“…These observations are entirely consistent with our model. In general, the curvature of the nanocrystal surface decreases at larger sizes and the ligands are forced closer to each other, 41 excluding solvent and increasing heterogeneity. However, for large nanocrystals, the curvature is already small and further increasing the nanocrystal size does not decrease the curvature significantly.…”

Section: Resultsmentioning

confidence: 99%

Solvent-Ligand Interactions in Colloidal Nanocrystals

Roo¹,

Yazdani²,

Drijvers³

et al. 2018

Preprint

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Although solvent-ligand interactions play a major role in nanocrystal synthesis, dispersion formulation and assembly, there is currently no direct method to study this. Here we examine the broadening of 1H NMR resonances associated with bound ligands, and turn this poorly understood descriptor into a tool to assess solvent-ligand interactions. We show that the line broadening has both a homogeneous and a heterogeneous component. The former is nanocrystal-size dependent and the latter results from solvent-ligand interactions. Our model is supported by experimental and theoretical evidence that correlates broad NMR lines with poor ligand solvation. This correlation is found across a wide range of solvents, extending from water to hexane, for both hydrophobic and hydrophilic ligand types, and for a multitude of oxide, sulfide and selenide nanocrystals. Our findings thus put forward NMR line shape analysis as an indispensable tool to form, investigate and manipulate nanocolloids.

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Section: Resultsmentioning

confidence: 99%

Solvent-Ligand Interactions in Colloidal Nanocrystals

Roo¹,

Yazdani²,

Drijvers³

et al. 2018

Preprint

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“…Moreover, the stability of thiol SAMs on Au surface can be evaluated by the well-known electrochemical reductive desorption method. [18] The position of the desorption peak potential in the reductive desorption process can be considered as a measure of SAMs stability. The reductive desorption data for the PET protected curved Au 144 showed two peaks at À 1.18 V and À 1.26 V vs. Ag/AgCl (Figure 3g).…”

Section: Solvent-limited Ion-coupled Electron Transfer and Monolayer mentioning

confidence: 99%

“…The relative difference of the desorption potential in the two system is~0.1 V. This data is in agreement with recent studies of electrochemical reductive desorption of alkanethiols on bulk Au and NP surfaces. [18] I.e., a higher reduction potential is required to desorb the thiols from the NPs (curved) surface compared to the bulk Au (flat) surface. The stability of thiol-based SAMs on the noble metal surfaces was dictated by various parameters, for example, intermolecular interactions, [19] AuÀ SÀ C bond angle (even-odd effect), [20] binding strength of AuÀ S on different facets [21] and the surrounding medium.…”

Section: Solvent-limited Ion-coupled Electron Transfer and Monolayer mentioning

confidence: 99%

“…Usually, the packing density of SAMs on the NP surface is lower than on the planar Au surface resulting in lower Van der Waals interactions between the molecules on the NP surface. [18,23] However, although, the packing density of alkanethiols on NPs is lower, they still exhibit greater chemical stability than thiols on a planar Au surface. [18] Similarly, the photothermal (light to heat) conversion efficiency is higher for Au nanoclusters and they hold the peripheral PET monolayers more strongly compared to the bulk Au surface, [24] as shown in figure 3e and 3f.…”

Section: Solvent-limited Ion-coupled Electron Transfer and Monolayer mentioning

confidence: 99%

“…[25] The tangential mode corresponds to the shorter AuÀ S bonds involved in the staple motif (Au(staple)-S(staple) bonds). These type of staple motif structures on the Au clusters are very well known, as evidenced by the X-ray structure of the crystallized cluster compounds such as Au 25 (PET) 18 , Au 38 (PET) 24 and many others. [26] While on the polycrystalline bulk Au surface (Figure 4b) two peaks centered at 293 and 322 cm À 1 with the different relative intensities were also observed.…”

Section: Solvent-limited Ion-coupled Electron Transfer and Monolayer mentioning

confidence: 99%

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Solvent‐Limited Ion‐Coupled Electron Transfer and Monolayer Thiol Stability in Au₁₄₄ Cluster Films

et al. 2018

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Voltammetric investigations were carried out for Au144 cluster films protected by 1‐hexanethiol (C6S) and 2‐phenylethanethiol (PET) in acetonitrile (0.1 M TBAPF6) and in water (0.1 M KPF6). The C6S‐protected Au144 cluster films show single electron charging behavior both in acetonitrile and water electrolyte systems. Whereas, the PET‐protected Au144 cluster films show charging behavior only in acetonitrile and not in water, although both electrolyte systems contain a common hydrophobic anion (PF6−). This discrepancy is attributed to solvent‐limited ion‐coupled electron‐transfer phenomena. Furthermore, spectroelectrochemistry was employed to study the thermal and electrochemical stability of PET on curved/3D (Au144 cluster films) and flat/2D (self‐assembled monolayers (SAMs) of PET on a polycrystalline planar Au electrode) Au surfaces. At 4 mW laser power, the SAMs of the curved system remained stable; however, in the flat system, they irreversibly desorb from the surface. This was ascribed to the relative stability differences of the PET monolayer originating from the existence of different Au−S structures on the two types of Au surfaces.

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Atroposelective Synthesis of 2,2′‐Bis(arylamino)‐1,1′‐biaryls by Oxidative Iron(III)‐ and Phosphoric Acid‐Catalyzed C−C Coupling of Diarylamines**

Fritsche

Schuh

Kataeva

et al. 2022

Chemistry A European J

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We describe an iron‐catalyzed asymmetric oxidative C−C coupling of diarylamines which proceeds at room temperature with air as final oxidant. Using hexadecafluorophthalocyanine‐iron(II) as catalyst in the presence of catalytic amounts of an axially chiral biaryl phosphoric acid, the resulting chiral 2,2′‐diamino‐1,1′‐biaryls are obtained in up to 90 % ee as confirmed by chiral HPLC. A detailed mechanism has been proposed with a radical cation‐chiral phosphate ion pair as key intermediate leading to the observed asymmetric induction.

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The van der Waals Interactions of n‐Alkanethiol‐Covered Surfaces: From Planar to Curved Surfaces

Cited by 12 publications

References 33 publications

Solvent-Ligand Interactions in Colloidal Nanocrystals

Solvent-Ligand Interactions in Colloidal Nanocrystals

Solvent‐Limited Ion‐Coupled Electron Transfer and Monolayer Thiol Stability in Au₁₄₄ Cluster Films

Atroposelective Synthesis of 2,2′‐Bis(arylamino)‐1,1′‐biaryls by Oxidative Iron(III)‐ and Phosphoric Acid‐Catalyzed C−C Coupling of Diarylamines**

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The van der Waals Interactions of n‐Alkanethiol‐Covered Surfaces: From Planar to Curved Surfaces

Cited by 12 publications

References 33 publications

Solvent-Ligand Interactions in Colloidal Nanocrystals

Solvent-Ligand Interactions in Colloidal Nanocrystals

Solvent‐Limited Ion‐Coupled Electron Transfer and Monolayer Thiol Stability in Au144 Cluster Films

Atroposelective Synthesis of 2,2′‐Bis(arylamino)‐1,1′‐biaryls by Oxidative Iron(III)‐ and Phosphoric Acid‐Catalyzed C−C Coupling of Diarylamines**

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Solvent‐Limited Ion‐Coupled Electron Transfer and Monolayer Thiol Stability in Au₁₄₄ Cluster Films