Asa Logan Roy scite author profile

Phosphides and carbides are among the most promising families of materials based on earth‐abundant elements for renewable energy conversion and storage technologies such as electrochemical water splitting, batteries, and capacitors. Nickel phosphide and molybdenum carbide in particular have been extensively investigated for electrochemical water splitting. However, a composite of the two compounds has not been explored. Here, we demonstrate preferential deposition of nickel phosphide on molybdenum carbide in the presence of carbon by using a hydrothermal synthesis method. We employ the hydrogen evolution reaction in acid and base to analyze the catalytic activity of phosphide‐deposited carbide. The composite material also shows superior electrochemical stability in comparison to unsupported phosphide. We anticipate that the enhanced electrochemical activity and stability of carbide deposited with phosphide will stimulate investigations into the preparation of other carbide–phosphide composite materials.

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Lattice Matched Carbide–Phosphide Composites with Superior Electrocatalytic Activity and Stability

Regmi

Roy

King

et al. 2017

Chem. Mater.

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Composites of electrocatalytically active transition metal compounds present an intriguing opportunity towards enhanced activity and stability. To identify potentially scalable pairs of catalytically active family of compounds, we demonstrate that phosphides of iron, nickel, and cobalt can be deposited on molybdenum carbide to generate nanocrystalline heterostructures. Composites synthesized via solvothermal decomposition of metal acetylacetonate salts in the presence of highly dispersed carbide nanoparticles show comparable hydrogen evolution activities to the state-of-the-art non-noble metal catalysts. Investigation of the spent catalyst using high resolution microscopy and elemental analysis reveals that formation of carbide-phosphide composite prevents catalyst dissolution in acid electrolyte. Lattice mismatch between the two constituent electrocatalysts can be used to rationally improve electrochemical stability. Among the composites of iron, nickel, and cobalt phosphide, iron phosphide displays the lowest degree of lattice mismatch with molybdenum carbide and shows optimal electrochemical stability. Turnover rates of the composites are higher than the carbide substrate and compare favorably to other electrocatalysts based on earth-abundant elements. Our findings will inspire further investigation into composite nanocrystalline electrocatalysts that implement molybdenum carbide as a stable catalyst support.

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Polystyrene‐based anion exchange membranes via click chemistry: improved properties and AEM performance

Tuli

Roy

Elgammal

et al. 2018

Polymer International

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Polystyrene-based anion exchange membranes (AEMs) have been fabricated using in situ click chemistry between azide and alkyne moieties introduced as side groups on functionalized polymers. The membrane properties such as water uptake, swelling ratio and conductivity were affected by the number of cations and the degree of crosslinking. The membranes containing a larger amount of trimethylammonium cationic groups (i.e. higher ion exchange capacity) showed high hydroxide conductivity when immersed in KOH solution, exhibiting a peak in conductivity (156 mS cm −1 ) in 3 mol L -1 KOH solution. A higher degree of crosslinking tended to decrease conductivity. These membranes demonstrated relatively good stability in 8 mol L -1 KOH at 60 ∘ C and maintained 33%-62% of initial conductivity after 49 days with most of the loss in conductivity occurring in early stages of the test. In an alkaline fuel cell, the areal specific resistance was constant indicating good stability of the membranes. The observed peak power density (157 mW cm −2 ) was comparable to that of other AEM-based fuel cells reported.

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Effect of morphology on anion conductive properties in self-assembled polystyrene-based copolymer membranes

Tuli

Roy

Elgammal

et al. 2018

Journal of Membrane Science

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Asa Logan Roy

Effect of CO2 absorption on ion and water mobility in an anion exchange membrane

Electrocatalytic Activity and Stability Enhancement through Preferential Deposition of Phosphide on Carbide

Lattice Matched Carbide–Phosphide Composites with Superior Electrocatalytic Activity and Stability

Polystyrene‐based anion exchange membranes via click chemistry: improved properties and AEM performance

Effect of morphology on anion conductive properties in self-assembled polystyrene-based copolymer membranes

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