Abstract
Composites of electrocatalytically active transition-metal compounds present an intriguing opportunity toward enhanced activity and stability. To identify potentially scalable pairs of a 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 hydrogen evolution activities comparable to those of 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 that of 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 use molybdenum carbide as a stable catalyst support.
Original language | English |
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Pages (from-to) | 9369-9377 |
Number of pages | 9 |
Journal | Chemistry of Materials |
Volume | 29 |
Issue number | 21 |
DOIs | |
State | Published - Nov 14 2017 |
Funding
This project was supported by Southeastern Sun Grant Center and the United States Department of Transportation, Research and Innovative Technology Administration DTO559-07-G-00050. N.L. and S.C.C. also acknowledge the Southeastern Partnership for Integrated Biomass Supply Systems (IBSS), which is supported by AFRI 2011-68005-30410 from USDA NIFA. XRD was performed at the Joint Institute for Advanced Materials (JIAM) by using instruments that were procured through the DOE Nuclear Energy University Program (DENE0000693) 12-3528. STEM, EELS, and XPS were performed at the Materials Science and Technology Division, Oak Ridge National Laboratory. The authors would like to thank Ms. Choo Hamilton at the Center for Renewable Carbon (CRC) for assistance with ICP-OES and Dr. Brian T. Sneed at the Center for Nanophase Materials Sciences, Oak Ridge National Laboratory for help with visualization software.
Funders | Funder number |
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AFRI | 2011-68005-30410 |
Southeastern Sun Grant Center | |
USDA NIFA | |
United States Department of Transportation, Research and Innovative Technology Administration | DTO559-07-G-00050 |