AI Article Synopsis
- Bimetallic metal-organic frameworks (MOFs) are effective in water electrocatalysis due to their large surface area and porous structure.
- A newly synthesized NiCo-MOF, induced by hexamethylene tetra-amine (HMT), shows promising results as a bifunctional electrocatalyst for water splitting in alkaline conditions, with low overpotential values for hydrogen and oxygen production.
- The catalyst demonstrated excellent electrochemical performance, including favorable reaction kinetics, significant capacitance, and impressive stability over extended operation, suggesting its potential for cost-effective hydrogen production.
Article Abstract
Bimetallic metal-organic frameworks (MOFs) play a significant role in the electrocatalysis of water due to their large surface area and availability of increased numbers of pores. For the inaugural time, we examine the effectiveness of a hexamethylene tetra-amine (HMT)-induced 3D NiCo-MOF-based nanostructure as a potent bifunctional electrocatalyst with superior performance for overall water splitting in alkaline environments. The structural, morphological, and electrochemical properties of the as-synthesized bifunctional catalyst were examined thoroughly before analyzing its behavior towards electrochemical water splitting. The HMT-based NiCo-MOF demonstrated small overpotential values of 274 mV and 330 mV in reaching a maximum current density of 30 mA cm for hydrogen and oxygen evolution mechanisms, respectively. The Tafel parameter also showed favorable HER/OER reaction kinetics, with slopes of 78 mV dec and 86 mV dec determined during the electrochemical evaluation. Remarkably, the NiCo-HMT electrode exhibited a double-layer capacitance of 4 mF cm for hydrogen evolution and 23 mF cm for oxygen evolution, while maintaining remarkable stability even after continuous operation for 20 hours. This research offers a valuable blueprint for implementing a cost-effective and durable MOF-based bifunctional catalytic system that has proven to be effective for complete water splitting. Decomposition of water under higher current densities is crucial for effective long-term generation and commercial consumption of hydrogen.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11046448 | PMC |
| http://dx.doi.org/10.1039/d4ra00340c | DOI Listing |
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