Robert E. Rettew scite author profile

The surface atomic structure and chemical state of Pt is consequential in a variety of surface-intensive devices. Herein we present the direct interrelationship between the growth scheme of Pt films, the resulting atomic and electronic structure of Pt species, and the consequent activity for methanol electro-oxidation in Pt/TiO(2) nanotube hybrid electrodes. X-ray photoelectron spectroscopy (XPS) and X-ray absorption spectroscopy (XAS) measurements were performed to relate the observed electrocatalytic activity to the oxidation state and the atomic structure of the deposited Pt species. The atomic structure as well as the oxidation state of the deposited Pt was found to depend on the pretreatment of the TiO(2) nanotube surfaces with electrodeposited Cu. Pt growth through Cu replacement increases Pt dispersion, and a separation of surface Pt atoms beyond a threshold distance from the TiO(2) substrate renders them metallic, rather than cationic. The increased dispersion and the metallic character of Pt results in strongly enhanced electrocatalytic activity toward methanol oxidation. This study points to a general phenomenon whereby the growth scheme and the substrate-to-surface-Pt distance dictates the chemical state of the surface Pt atoms, and thereby, the performance of Pt-based surface-intensive devices.

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Layer-by-Layer Pt Growth on Polycrystalline Au: Surface-Limited Redox Replacement of Overpotentially Deposited Ni Monolayers

Rettew¹,

Guthrie²,

Alamgir³

2009

J. Electrochem. Soc.

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The catalyst system Pt/Au has been the subject of many studies recently, ranging from formic acid oxidation to oxidative studies for direct alcohol fuel cells. This paper outlines the use of overpotential Ni deposition as an intermediary for the creation of model overlayer/substrate Pt/Au catalysts with atomic monolayer (ML)-level thickness control. Deposition of Pt on polycrystalline Au was conducted via Ni surface-limited redox replacement. By electrodepositing a controlled layer of Ni on Au and exposing the resultant surface to Pt in solution, then repeating this technique for multiple iterations, Pt atomic MLs were electrolessly deposited on top of one another. The growth of Pt overlayers was demonstrated by X-ray photoelectron spectroscopy. The use of Ni as the replacement layer, as opposed to the commonly used Cu, opens up a range of metals for layer-by-layer deposition.

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Architecture-Dependent Surface Chemistry for Pt Monolayers on Carbon-Supported Au

Cheng

Rettew

Sauerbrey

et al. 2011

ACS Appl. Mater. Interfaces

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Pt monolayers were grown by surface-limited redox replacement (SLRR) on two types of Au nanostructures. The Au nanostructures were fabricated electrochemically on carbon fiber paper (CFP) by either potentiostatic deposition (PSD) or potential square wave deposition (PSWD). The morphology of the Au/CFP heterostructures, examined using scanning electron microscopy (SEM), was found to depend on the type of Au growth method employed. The properties of the Pt deposit, as studied using X-ray photoelectron spectroscopy (XPS), X-ray absorption spectroscopy (XAS), and cyclic voltammetry (CV), were found to depend strongly on the morphology of the support. Specifically, it was found that smaller Au morphologies led to a higher degree of cationicity in the resulting Pt deposit, with Pt(4+) and Pt(2+) species being identified using XPS and XAS. For fuel-cell catalysts, the resistance of ultrathin catalyst deposits to surface area loss through dissolution, poisoning, and agglomeration is critical. This study shows that an equivalent of two monolayers (ML) is the low-loading limit of Pt on Au. At 1 ML or below, the Pt film decreases in activity and durability very rapidly due to presence of cationic Pt.

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Electrical polarization of titanium surfaces for the enhancement of osteoblast differentiation

Gittens

Olivares-Navarrete

Rettew

et al. 2013

Bioelectromagnetics

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Electrical stimulation has been used clinically to promote bone regeneration in cases of fractures with delayed union or nonunion, with several in vitro and in vivo reports suggesting its beneficial effects on bone formation. However, the use of electrical stimulation of titanium (Ti) implants to enhance osseointegration is less understood, in part because of the few in vitro models that attempt to represent the in vivo environment. In this article, the design of a new in vitro system that allows direct electrical stimulation of osteoblasts through their Ti substrates without the flow of exogenous currents through the media is presented, and the effect of applied electrical polarization on osteoblast differentiation and local factor production was evaluated. A custom-made polycarbonate tissue culture plate was designed to allow electrical connections directly underneath Ti disks placed inside the wells, which were supplied with electrical polarization ranging from 100 to 500 mV to stimulate MG63 osteoblasts. Our results show that electrical polarization applied directly through Ti substrates on which the cells are growing in the absence of applied electrical currents may increase osteoblast differentiation and local factor production in a voltage-dependent manner.

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Robert E. Rettew

A Phenomenological Study of the Metal–Oxide Interface: The Role of Catalysis in Hydrogen Production from Renewable Resources

Interface Architecture Determined Electrocatalytic Activity of Pt on Vertically Oriented TiO2 Nanotubes

Layer-by-Layer Pt Growth on Polycrystalline Au: Surface-Limited Redox Replacement of Overpotentially Deposited Ni Monolayers

Architecture-Dependent Surface Chemistry for Pt Monolayers on Carbon-Supported Au

Electrical polarization of titanium surfaces for the enhancement of osteoblast differentiation

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Interface Architecture Determined Electrocatalytic Activity of Pt on Vertically Oriented TiO₂ Nanotubes