Paul F. Rottmann scite author profile

We report on Cu nanowires as highly active and selective catalysts for electroreduction of CO at low overpotentials. The Cu nanowires were synthesized by reducing pregrown CuO nanowires, with the surface structures tailored by tuning the reduction conditions for improved catalytic performance. The optimized Cu nanowires achieved 65% faradaic efficiency (FE) for CO reduction and 50% FE toward production of ethanol at potentials more positive than −0.5 V (versus reversible hydrogen electrode, RHE). Structural analyses and computational simulations suggest that the CO reduction activity may be associated with the coordinately unsaturated (110) surface sites on the Cu nanowires.

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Characterizing deformed ultrafine-grained and nanocrystalline materials using transmission Kikuchi diffraction in a scanning electron microscope

Trimby

et al. 2014

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Mechanistic Insights for Low-Overpotential Electroreduction of CO₂ to CO on Copper Nanowires

et al. 2017

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Recent developments of copper (Cu)-based nanomaterials have enabled the electroreduction of CO 2 at low overpotentials. The mechanism of low-overpotential CO 2 reduction on these nanocatalysts, however, largely remains elusive. We report here a systematic investigation of CO 2 reduction on highly dense Cu nanowires, with the focus placed on understanding the surface structure effects on the formation of *CO (* denotes an adsorption site on the catalyst surface) and the evolution of gas-phase CO product (CO(g)) at low overpotentials (more positive than −0.5 V). Cu nanowires of distinct nanocrystalline and surface structures are studied comparatively to build up the structure−property relationships, which are further interpreted by performing density functional theory (DFT) calculations of the reaction pathway on the various facets of Cu. A kinetic model reveals competition between CO(g) evolution and *CO poisoning depending on the electrode potential and surface structures. Open and metastable facets such as (110) and reconstructed (110) are found to be likely the active sites for the electroreduction of CO 2 to CO at the low overpotentials.

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Multiplicity of dislocation pathways in a refractory multiprincipal element alloy

Wang

Balbus

et al. 2020

Science

227

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Refractory multiprincipal element alloys (MPEAs) are promising materials to meet the demands of aggressive structural applications, yet require fundamentally different avenues for accommodating plastic deformation in the body-centered cubic (bcc) variants of these alloys. We show a desirable combination of homogeneous plastic deformability and strength in the bcc MPEA MoNbTi, enabled by the rugged atomic environment through which dislocations must navigate. Our observations of dislocation motion and atomistic calculations unveil the unexpected dominance of nonscrew character dislocations and numerous slip planes for dislocation glide. This behavior lends credence to theories that explain the exceptional high temperature strength of similar alloys. Our results advance a defect-aware perspective to alloy design strategies for materials capable of performance across the temperature spectrum.

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TriBeam tomography and microstructure evolution in additively manufactured Alnico magnets

et al. 2021

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Paul F. Rottmann

Low-Overpotential Electroreduction of Carbon Monoxide Using Copper Nanowires

Characterizing deformed ultrafine-grained and nanocrystalline materials using transmission Kikuchi diffraction in a scanning electron microscope

Mechanistic Insights for Low-Overpotential Electroreduction of CO₂ to CO on Copper Nanowires

Multiplicity of dislocation pathways in a refractory multiprincipal element alloy

TriBeam tomography and microstructure evolution in additively manufactured Alnico magnets

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Paul F. Rottmann

Low-Overpotential Electroreduction of Carbon Monoxide Using Copper Nanowires

Characterizing deformed ultrafine-grained and nanocrystalline materials using transmission Kikuchi diffraction in a scanning electron microscope

Mechanistic Insights for Low-Overpotential Electroreduction of CO2 to CO on Copper Nanowires

Multiplicity of dislocation pathways in a refractory multiprincipal element alloy

TriBeam tomography and microstructure evolution in additively manufactured Alnico magnets

Contact Info

Product

Resources

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Mechanistic Insights for Low-Overpotential Electroreduction of CO₂ to CO on Copper Nanowires