Abstract
Progress in electrochemical water-splitting devices as future renewable and clean energy systems requires the development of electrodes composed of efficient and earth-abundant bifunctional electrocatalysts. This study reveals a novel flexible and bifunctional electrode (NiO@CNTR) by hybridizing macroscopically assembled carbon nanotube ribbons (CNTRs) and atmospheric plasma-synthesized NiO quantum dots (QDs) with varied loadings to demonstrate bifunctional electrocatalytic activity for stable and efficient overall water-splitting (OWS) applications. Comparative studies on the effect of different electrolytes, e.g., acid and alkaline, reveal a strong preference for alkaline electrolytes for the developed NiO@CNTR electrode, suggesting its bifunctionality for both HER and OER activities. Our proposed NiO@CNTR electrode demonstrates significantly enhanced overall catalytic performance in a two-electrode alkaline electrolyzer cell configuration by assembling the same electrode materials as both the anode and the cathode, with a remarkable long-standing stability retaining ∼100% of the initial current after a 100 h long OWS run, which is attributed to the “synergistic coupling” between NiO QD catalysts and the CNTR matrix. Interestingly, the developed electrode exhibits a cell potential (E10) of only 1.81 V with significantly low NiO QD loading (83 μg/cm2) compared to other catalyst loading values reported in the literature. This study demonstrates a potential class of carbon-based electrodes with single-metal-based bifunctional catalysts that opens up a cost-effective and large-scale pathway for further development of catalysts and their loading engineering suitable for alkaline-based OWS applications and green hydrogen generation.
Original language | English |
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Pages (from-to) | 12339–12352 |
Number of pages | 14 |
Journal | ACS Applied Materials and Interfaces |
Volume | 16 |
Issue number | 10 |
Early online date | 1 Mar 2024 |
DOIs | |
Publication status | Published - 13 Mar 2024 |
Keywords
- alkaline electrolyzer cell
- bifunctional and flexible electrode
- hydrogen evolution reaction (HER)
- long-term OWS stability
- macroscopically assembled carbon nanotube (CNT) ribbons
- nickel oxides (NiO) quantum dots (QDs)
- overall water splitting (OWS) in alkaline media
- oxygen evolution reaction (OER)
- plasma-induced nonequilibrium electrochemistry (PiNE)
- water electrolysis