Editors' Choice—A Methodology to Electrochemically Fabricate Fe-Ni-Co Nanotips

Geng, Xiwen; Liang, Wentao; Podlaha, E. J.

doi:10.1149/2.1031704jes

Cited by 8 publications

(16 citation statements)

References 40 publications

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“…Locally, the composition could change along the nanowire length if one of the metal rates were under mass transport control, or if the pH changes. Both Fe and Ni ion reduction are expected to be under predominately kinetic control, but Co may be influenced by mass transport changes The change in current efficiency as the nanowire grows could also change the local pH and hence composition, as reported by Geng et al 17 for the same electrolyte presented here. Deligianni and Romankiw 43 have confirmed a surface pH rise during Ni-Fe thin film deposition.…”

Section: Discussionsupporting

confidence: 67%

Template-Assisted Electrodeposition of Fe-Ni-Co Nanowires: Effects of Electrolyte pH and Sodium Lauryl Sulfate

Podlaha

2017

J. Electrochem. Soc.

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The influence of pH and sodium lauryl sulfate (SLS) electrolyte composition on the potentiostatic, template-assisted electrodeposition of Fe-Ni-Co alloy nanowires into alumina nanoporous membranes with a large accompanying hydrogen side reaction is presented. Solid nanowires and tubular, composite tips were observed and the average alloy composition was characterized. The growth of nanowires was insensitive to SLS at pH values of 2.0, but was a strong function of SLS at a low pH of 0.5. Anomalous codeposition was evident and the Fe-rich alloy nanowires were independent of SLS concentration at pH values above 0.5. The change in deposition rate and alloy composition was attributed to changes in adsorbed species: metal ion intermediates, hydrogen ion, hydrogen gas bubbles and SLS.

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Section: Discussionsupporting

confidence: 67%

Template-Assisted Electrodeposition of Fe-Ni-Co Nanowires: Effects of Electrolyte pH and Sodium Lauryl Sulfate

Podlaha

2017

J. Electrochem. Soc.

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“…FeNiCo composite nanowires were pulsed electrodeposited in a nanoporous alumina template with 0.2 μm diameter pores and up to 30 μm in length. Details on the electrodeposition process can be found in [51]. After the electrodeposition, the alumina template was dissolved with a 2 M NaOH solution overnight.…”

Section: Methodsmentioning

confidence: 99%

Patterned electromagnetic alignment of magnetic nanowires

Beheshti

Choi

Geng

et al. 2018

Microelectronic Engineering

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A combination of electromagnetic alignment and topological pattern assisted alignment to position magnetic nanowires, which is referred to as the Patterned Electromagnetic Alignment (PEA), is developed and examined. Electrodeposited, FeNiCo nanowires with different lengths were used as the test nanomaterial, and the microscale grooved surface was formed by UV nanoimprint lithography. The accuracy of the PEA with FeNiCo nanowires was evaluated by measuring the deviation angle from the direction of the magnetic field line for different magnetic field strengths and nanowire lengths, and a statistical alignment distribution was reported for different nanowire length groups. The results were compared with those of the electromagnetic alignment on flat surfaces and in grooved-patterned substrates without electromagnetic alignment. Overall, the deviation angle for the PEA was lower than that for the electromagnetic alignment when all other experimental conditions were identical, indicating that the alignment accuracy along the direction of the magnetic field lines was enhanced in the presence of surface micro grooves. This can be attributed to the fact that, upon attachment of nanowires to the substrate surface, the surface micro grooves in the PEA add additional deterministic characteristics to the otherwise stochastic nature of the nanowire deposition and solvent evaporation processes compared to the sole electromagnetic alignment.

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“…Fe−Ni−Co thin films were electrodeposited galvanostatically from a sulfate/sulfamate−boric acid electrolyte (details in Supporting Information, Table S1), adapted from Kim et al 36 and Geng et al 37 Copper rotating cylinder electrodes (RCEs) having a diameter of 1 cm and length of 1.2 cm served as the working electrode with Pt as the counter electrode. The RCE is not flush with the top and bottom insulating regions of the plastic holder, but it is recessed, making a right angle between the plastic holder and the copper electrode, to facilitate a uniform current density distribution.…”

mentioning

confidence: 99%

Activity and Regeneration of Electrodeposited Fe–Ni–Co-Based Electrocatalysts for the Alkaline Oxygen Evolution Reaction

Zhang

Kizilkaya

Bilan

et al. 2020

ACS Appl. Energy Mater.

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A methodology to recover the oxygen evolution reaction (OER) kinetics of aged, electrodeposited Fe−Ni−Co thin films is presented. The electrodeposits were fabricated galvanostatically onto rotating copper electrodes and contained a small amount of Co. The OER characterized in 1 M KOH was a function of the deposit composition. The Tafel slope and the overpotential at 10 mA/cm 2 observed with ohmically corrected linear sweep voltammetry were both a function of the deposit metal ratio, Fe/(Ni + Co), with the lowest values occurring at a ratio of 1.2. An Fe-rich deposit was purposely altered upon aging to degrade the OER kinetics. The Tafel slope and overpotential were largely recovered when the aged electrocatalyst was treated with a cathodic current density of −100 mA/cm 2 for 10 min. Soft X-ray absorption spectroscopy provided insight into the changes of the electron density distribution upon aging and regenerating the electrocatalyst. Through X-ray absorption near-edge structure (XANES), the L-edge spectra of Fe, Ni, Co, and K-edge spectra of O, suggested that the recovery is due to the redistribution of the electron density from the oxygen to Fe and Ni.

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Editors' Choice—A Methodology to Electrochemically Fabricate Fe-Ni-Co Nanotips

Cited by 8 publications

References 40 publications

Template-Assisted Electrodeposition of Fe-Ni-Co Nanowires: Effects of Electrolyte pH and Sodium Lauryl Sulfate

Template-Assisted Electrodeposition of Fe-Ni-Co Nanowires: Effects of Electrolyte pH and Sodium Lauryl Sulfate

Patterned electromagnetic alignment of magnetic nanowires

Activity and Regeneration of Electrodeposited Fe–Ni–Co-Based Electrocatalysts for the Alkaline Oxygen Evolution Reaction

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