TY - JOUR
T1 - Self-Powered Hydrogen Production From Seawater Enabled by Trifunctional Exfoliated PtTe Nanosheet Catalysts
AU - Yu, Zhipeng
AU - D'Olimpio, Gianluca
AU - Huang, Haoliang
AU - Kuo, Chia Nung
AU - Lue, Chin Shan
AU - Nicotra, Giuseppe
AU - Lin, Fei
AU - Boukhvalov, Danil W.
AU - Politano, Antonio
AU - Liu, Lifeng
N1 - Publisher Copyright:
© 2024 Wiley-VCH GmbH.
PY - 2024/9/25
Y1 - 2024/9/25
N2 - Seawater electrolysis (SWE) is proposed to be a promising approach to green hydrogen (H2) production but its large-scale deployment faces challenges because of the anodic competing chlorine evolution reaction (CER) and high energy consumption. To address these challenges, innovative hybrid SWE systems have recently emerged, able to mitigate the interference of CER and substantially reduce the electrical energy needed. Herein, the preparation of 2D layered PtTe nanosheets (e-PtTe NSs) using the liquid-phase exfoliation method is reported, which show outstanding electrocatalytic performance for the hydrogen evolution (HER), hydrazine oxidation (HzOR), and oxygen reduction reactions (ORR) in seawater. Using e-PtTe NSs as trifunctional catalysts, two hybrid SWE systems are demonstrated: 1) a hydrazine-assisted acid-alkaline dual-electrolyte seawater electrolyzer enabled by a bipolar membrane (BPM-OHzSWE), which can simultaneously produce H2 and generate electricity through harvesting the electrochemical neutralization energy and leveraging the advantage of the HzOR over the oxygen evolution reaction (OER) in terms of anodic potentials; 2) a hydrazine-assisted SWE system powered by a direct hydrazine fuel cell (DHzFC), which can realize self-powered H2 production. These novel hybrid SWE systems show substantial promise for energy-saving and cost-effective production of H2 from seawater.
AB - Seawater electrolysis (SWE) is proposed to be a promising approach to green hydrogen (H2) production but its large-scale deployment faces challenges because of the anodic competing chlorine evolution reaction (CER) and high energy consumption. To address these challenges, innovative hybrid SWE systems have recently emerged, able to mitigate the interference of CER and substantially reduce the electrical energy needed. Herein, the preparation of 2D layered PtTe nanosheets (e-PtTe NSs) using the liquid-phase exfoliation method is reported, which show outstanding electrocatalytic performance for the hydrogen evolution (HER), hydrazine oxidation (HzOR), and oxygen reduction reactions (ORR) in seawater. Using e-PtTe NSs as trifunctional catalysts, two hybrid SWE systems are demonstrated: 1) a hydrazine-assisted acid-alkaline dual-electrolyte seawater electrolyzer enabled by a bipolar membrane (BPM-OHzSWE), which can simultaneously produce H2 and generate electricity through harvesting the electrochemical neutralization energy and leveraging the advantage of the HzOR over the oxygen evolution reaction (OER) in terms of anodic potentials; 2) a hydrazine-assisted SWE system powered by a direct hydrazine fuel cell (DHzFC), which can realize self-powered H2 production. These novel hybrid SWE systems show substantial promise for energy-saving and cost-effective production of H2 from seawater.
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U2 - 10.1002/adfm.202403099
DO - 10.1002/adfm.202403099
M3 - Article
AN - SCOPUS:85190457117
SN - 1616-301X
VL - 34
JO - Advanced Functional Materials
JF - Advanced Functional Materials
IS - 39
M1 - 2403099
ER -