Joshua Z. Ginges scite author profile

Joshua Z. Ginges

3Publications

55Citation Statements Received

107Citation Statements Given

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100

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UNSW Sydney

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Some More Observations on the Unique Electrochemical Properties of Electrode–Monolayer–Nanoparticle Constructs

et al. 2010

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Physical and electrochemical properties of gold nanoparticle-based electrodes are highlighted. Polycrystalline gold electrodes are passivated by a self-assembled monolayer, then the immobilization of gold nanoparticles "switch on" the electrochemical reactivity of ruthenium. Herein, gap-mode Raman studies show that the location of the nanoparticles is on the top of the monolayer, meaning that the "switching on" cannot be attributed to a direct electrical contact between nanoparticles and the gold support. This "switching on" feature is also not affected by the size of the gold nanoparticles with a range of diameters between 4 and 67 nm. Further, the charge of the nanoparticles is investigated by grafting chemical groups onto the nanoparticles which is observed to alter the electron-transfer kinetics. The variation in rate constant however is insufficient to attribute the "switching on" phenomenon to a possible adsorption of the redox species onto the nanoparticles.

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Protein Resistance of Surfaces Modified with Oligo(Ethylene Glycol) Aryl Diazonium Derivatives

Fairman¹,

Ginges²,

Lowe³

et al. 2013

ChemPhysChem

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Anti-fouling surfaces are of great importance for reducing background interference in biosensor signals. Oligo(ethylene glycol) (OEG) moieties are commonly used to confer protein resistance on gold, silicon and carbon surfaces. Herein, we report the modification of surfaces using electrochemical deposition of OEG aryl diazonium salts. Using electrochemical and contact angle measurements, the ligand packing density is found to be loose, which supports the findings of the fluorescent protein labelling that aryl diazonium OEGs confer resistance to nonspecific adsorption of proteins albeit lower than alkane thiol-terminated OEGs. In addition to protein resistance, aryl diazonium attachment chemistry results in stable modification. In common with OEG species on gold electrodes, OEGs with distal hydroxyl moieties do confer superior protein resistance to those with a distal methoxy group. This is especially the case for longer derivatives where superior coiling of the OEG chains is possible.

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Inside Cover: Some More Observations on the Unique Electrochemical Properties of Electrode–Monolayer–Nanoparticle Constructs (ChemPhysChem 13/2010)

et al. 2010

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Joshua Z. Ginges

Some More Observations on the Unique Electrochemical Properties of Electrode–Monolayer–Nanoparticle Constructs

Protein Resistance of Surfaces Modified with Oligo(Ethylene Glycol) Aryl Diazonium Derivatives

Inside Cover: Some More Observations on the Unique Electrochemical Properties of Electrode–Monolayer–Nanoparticle Constructs (ChemPhysChem 13/2010)

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