Charge-Transfer Patterns for [Ru(NH3)6]3+/2+ at SAM Modified Gold Electrodes: Impact of the Permeability of a Redox Probe

Dolidze, Tina D.; Rondinini, Sandra; Vertova, Alberto; Longhi, Mariangela; Khoshtariya, Dimitri E.

doi:10.2174/1874067700802010017

Cited by 7 publications

(5 citation statements)

References 33 publications

(136 reference statements)

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“…The permeability and stability of SAMs on planar or nanoparticle metal substrates are usually inferred from the voltammetric behavior of the SAM-coated substrates in the presence of redox-active molecular species. Many careful studies, most often on SAMs of alkylthiolates or disulfides on planar gold, have mapped the electrical current produced through heterogeneous charge transfer from the conductive substrate to a molecular probe as a function of intra- and intermolecular structural characteristics of the SAM, including the length, bulkiness, and conjugation of these organic molecules, the charge of the chain’s terminal group, and the packing orders of ligands. − …”

Section: Role Of Molecules In Energy and Charge Transfer Involving Co...mentioning

confidence: 99%

Electronic Processes within Quantum Dot-Molecule Complexes

et al. 2016

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The subject of this review is the colloidal quantum dot (QD) and specifically the interaction of the QD with proximate molecules. It covers various functions of these molecules, including (i) ligands for the QDs, coupled electronically or vibrationally to localized surface states or to the delocalized states of the QD core, (ii) energy or electron donors or acceptors for the QDs, and (iii) structural components of QD assemblies that dictate QD-QD or QD-molecule interactions. Research on interactions of ligands with colloidal QDs has revealed that ligands determine not only the excited state dynamics of the QD but also, in some cases, its ground state electronic structure. Specifically, the article discusses (i) measurement of the electronic structure of colloidal QDs and the influence of their surface chemistry, in particular, dipolar ligands and exciton-delocalizing ligands, on their electronic energies; (ii) the role of molecules in interfacial electron and energy transfer processes involving QDs, including electron-to-vibrational energy transfer and the use of the ligand shell of a QD as a semipermeable membrane that gates its redox activity; and (iii) a particular application of colloidal QDs, photoredox catalysis, which exploits the combination of the electronic structure of the QD core and the chemistry at its surface to use the energy of the QD excited state to drive chemical reactions.

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Section: Role Of Molecules In Energy and Charge Transfer Involving Co...mentioning

confidence: 99%

Electronic Processes within Quantum Dot-Molecule Complexes

et al. 2016

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“…Efficient extraction of photogenerated charge carriers from colloidal semiconductor QDs is essential to their application as photovoltaically and photocatalytically active materials . The organic ligand shell that electronically passivates − and solubilizes colloidal QDs also presents a physical barrier that impedes a molecular redox partner’s approach to the QD surface and limits the number of available sites per QD for its adsorption. − The ligand shell therefore acts as a semipermeable self-assembled monolayer (SAM), the properties of which are traditionally investigated through the voltammetric behavior of SAM-coated planar or nanoparticulate metal substrates in the presence of electroactive molecular species. − Many careful studies, most often on SAMs of alkylthiols or disulfides on planar gold, have mapped the electrical current produced through heterogeneous charge transfer from the conductive substrate to a molecular probe to intra- and intermolecular structural characteristics of the SAM, including the length and saturation of alkyl chains, the charge of the chain’s terminal group, and the density of pinholes, “thin” regions, and adventitious adsorbates. ,− …”

Section: Introductionmentioning

confidence: 99%

Electron Transfer as a Probe of the Permeability of Organic Monolayers on the Surfaces of Colloidal PbS Quantum Dots

et al. 2013

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“…The permeability of an organic adlayer on a QD can be inferred from the rate and yield of charge transfer (CT) between the QD and a redox-active probe molecule because CT between the QD and a molecule is dominated by pathways that bypass the electrically insulating layer. In the great majority of cases, CT only occurs for molecules that permeate the ligand shell and are within the tunneling radius of the QD, typically a few angstroms from the inorganic surface. , Previous studies have used cyclic voltammetry (CV) and scanning tunneling microscopy to detect heterogeneous charge transfer from conductive substrates, most frequently planar gold, to molecular probes to study intra- and intermolecular structural characteristics of the SAM, such as the conformation and tilt-angle of the molecules, the charge distribution, and the density of pinholes, “thin” regions, and adventitious adsorbates. − ,− The relationship between the structure of an organic adlayer on a semiconductor QD and the QD’s redox activity is not, however, directly analogous to (or predictable from) that relationship for a planar metal surface, as the high curvature of nanoparticle surfacesand the presence of facets, edges, and verticesinfluence the organization and density of molecules on these surfaces. ,,− Furthermore, planar surfaces and metal NPs are amenable to CV, whereas QDs tend to undergo irreversible redox reactions and precipitate from solution under relevant applied voltages.…”

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confidence: 99%

Temperature-Dependent Permeability of the Ligand Shell of PbS Quantum Dots Probed by Electron Transfer to Benzoquinone

Aruda

Kunz

Tagliazucchi

et al. 2015

J. Phys. Chem. Lett.

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This paper describes an increase in the yield of collisionally gated photoinduced electron transfer (electron transfer events per collision) from oleate-capped PbS quantum dots (QDs) to benzoquinone (BQ) with increasing temperature (from 0 to 50 °C), due to increased permeability of the oleate adlayer of the QDs to BQ. The same changes in intermolecular structure of the adlayer that increase its permeability to BQ also increase its permeability to the solvent, toluene, resulting in a decrease in viscous drag and an apparent increase in the diffusion coefficient of the QDs, as measured by diffusion-ordered spectroscopy (DOSY) NMR. Comparison of NMR and transient absorption spectra of QDs capped with flexible oleate with those capped with rigid methylthiolate provides evidence that the temperature dependence of the permeability of the oleate ligand shell is due to formation of transient gaps in the adlayer through conformational fluctuations of the ligands.

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Charge-Transfer Patterns for [Ru(NH3)6]3+/2+ at SAM Modified Gold Electrodes: Impact of the Permeability of a Redox Probe

Cited by 7 publications

References 33 publications

Electronic Processes within Quantum Dot-Molecule Complexes

Electronic Processes within Quantum Dot-Molecule Complexes

Electron Transfer as a Probe of the Permeability of Organic Monolayers on the Surfaces of Colloidal PbS Quantum Dots

Temperature-Dependent Permeability of the Ligand Shell of PbS Quantum Dots Probed by Electron Transfer to Benzoquinone

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