Recent advances in surface functionalized 3D electrocatalyst for water splitting
Recent advances in surface functionalized 3D electrocatalyst for water splitting
Hydrogen is gaining attention as a fossil fuel alternative due to its potential to meet global energy demands. Producing hydrogen from water splitting is promising as a clean and sustainable fuel pathway. The hydrogen evolution reactions (HER) and oxygen evolution reaction (OER) are crucial in electrocatalytic water splitting for energy conversion and storage. However, water electrolysis faces challenges in cost, efficiency, and scalability. Alternative transition metal electrocatalysts and emerging 2D materials advance electrolysis research, though transitioning from academia to industry remains challenging. The introduction of 3D-printing technologies has revolutionized electrode fabrication for HER and OER. This review explores integrating 3D-printing technologies and surface functionalization with non-noble metal-based electrocatalysts and emerging 2D materials. It focuses on surface-functionalized 3D-printed electrodes using technologies like selective laser melting, stereolithography, and fused deposition modelling with non-noble metal electrocatalysts such as transition metal oxides, hydroxides, and emerging 2D materials like transition metal carbide/nitride (MXenes) and transition metal dichalcogenides (TMDCs). The review highlights the opportunities and challenges in scalable fabrication, long-term durability, and cost-efficiency for practical implementation. Future research directions include exploring new materials for 3D printing and alternative electrocatalysts alongside leveraging theoretical and machine-learning approaches to accelerate the development of competitive materials for water electrolysis.
Meethale Palakkool, Nadira
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Taverne, Mike P.C.
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Bell, Owen
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Mar, Jonathan D.
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Barrioz, Vincent
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Qu, Yongtao
943c307c-14c3-4ae0-bb11-246983cd5667
Huang, Kevin Chung-Che
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Ho, Y.-L. Daniel
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Meethale Palakkool, Nadira
7ff30e79-5012-4cac-96b3-ec461fc65023
Taverne, Mike P.C.
6444e2cd-5d52-43a7-83b6-2e72f922501d
Bell, Owen
42e3e1c3-b70e-48d1-8b58-de53bfaef1ea
Mar, Jonathan D.
271920e7-e410-4a0a-9ad8-389ba3fe36f3
Barrioz, Vincent
56edf13a-1bed-4e5b-bc03-2c7de8426d15
Qu, Yongtao
943c307c-14c3-4ae0-bb11-246983cd5667
Huang, Kevin Chung-Che
825f7447-6d02-48f6-b95a-fa33da71f106
Ho, Y.-L. Daniel
945e3431-b334-4d98-858f-c3fae452640f
Meethale Palakkool, Nadira, Taverne, Mike P.C., Bell, Owen, Mar, Jonathan D., Barrioz, Vincent, Qu, Yongtao, Huang, Kevin Chung-Che and Ho, Y.-L. Daniel
(2024)
Recent advances in surface functionalized 3D electrocatalyst for water splitting.
Advanced Energy and Sustainability Research.
(In Press)
Abstract
Hydrogen is gaining attention as a fossil fuel alternative due to its potential to meet global energy demands. Producing hydrogen from water splitting is promising as a clean and sustainable fuel pathway. The hydrogen evolution reactions (HER) and oxygen evolution reaction (OER) are crucial in electrocatalytic water splitting for energy conversion and storage. However, water electrolysis faces challenges in cost, efficiency, and scalability. Alternative transition metal electrocatalysts and emerging 2D materials advance electrolysis research, though transitioning from academia to industry remains challenging. The introduction of 3D-printing technologies has revolutionized electrode fabrication for HER and OER. This review explores integrating 3D-printing technologies and surface functionalization with non-noble metal-based electrocatalysts and emerging 2D materials. It focuses on surface-functionalized 3D-printed electrodes using technologies like selective laser melting, stereolithography, and fused deposition modelling with non-noble metal electrocatalysts such as transition metal oxides, hydroxides, and emerging 2D materials like transition metal carbide/nitride (MXenes) and transition metal dichalcogenides (TMDCs). The review highlights the opportunities and challenges in scalable fabrication, long-term durability, and cost-efficiency for practical implementation. Future research directions include exploring new materials for 3D printing and alternative electrocatalysts alongside leveraging theoretical and machine-learning approaches to accelerate the development of competitive materials for water electrolysis.
Text
Recent advances in Surface Functionalized 3D Electrocatalyst for Water Splitting-final version
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Accepted/In Press date: 7 November 2024
Identifiers
Local EPrints ID: 496086
URI: http://eprints.soton.ac.uk/id/eprint/496086
ISSN: 2699-9412
PURE UUID: 0e8e40f7-ecaf-4dea-a370-d53d4c20d335
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Date deposited: 03 Dec 2024 17:39
Last modified: 04 Dec 2024 02:41
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Contributors
Author:
Nadira Meethale Palakkool
Author:
Mike P.C. Taverne
Author:
Owen Bell
Author:
Jonathan D. Mar
Author:
Vincent Barrioz
Author:
Yongtao Qu
Author:
Kevin Chung-Che Huang
Author:
Y.-L. Daniel Ho
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