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Surface excited MoO2 to master full water splitting

•MoO2 nanosheets were fabricated on nickel foam through hydrothermal method.•Post-modification by Hydrazine solution could introduce oxygen vacancies to the surface of MoO2 nanosheets.•Oxygen vacancies enhanced conductivity and improved surface reaction kinetics of MoO2.•The post-treatment process f...

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Published in:Electrochimica acta 2020-11, Vol.359, p.136929, Article 136929
Main Authors: Wang, Bobo, Zhang, Zhe, Zhang, Shanshan, Cao, Yuncheng, Su, Yong, Liu, Shude, Tang, Wei, Yu, Junxi, Ou, Yun, Xie, Shuhong, Li, Jiangyu, Ma, Ming
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cited_by cdi_FETCH-LOGICAL-c343t-245e89009c7bd4aa3f744af9aa1a7d847ca63c0f3fda4e6d0b3debcd3699b4563
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container_title Electrochimica acta
container_volume 359
creator Wang, Bobo
Zhang, Zhe
Zhang, Shanshan
Cao, Yuncheng
Su, Yong
Liu, Shude
Tang, Wei
Yu, Junxi
Ou, Yun
Xie, Shuhong
Li, Jiangyu
Ma, Ming
description •MoO2 nanosheets were fabricated on nickel foam through hydrothermal method.•Post-modification by Hydrazine solution could introduce oxygen vacancies to the surface of MoO2 nanosheets.•Oxygen vacancies enhanced conductivity and improved surface reaction kinetics of MoO2.•The post-treatment process for oxygen vacancies provides an effective strategy for improving electrocatalysis. Electrocatalytic water splitting, including hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), is an ideal method to produce hydrogen energy source. Stable electrocatalysts with good electrolytic activity are crucial for long-term water splitting. In this work, we show that MoO2 nanosheets can be grown directly on nickel foam substrate with oxygen vacancies decorated on the surface, acting as an excellent electrocatalyst for practical water splitting. In comparison to the pristine sample, the optimized MoO2, treated by 2% N2H4 solution for 20 min, exhibits a relatively low onset potential of −60 mV vs. reversible hydrogen electrode (RHE) for HER and a cell voltage of about 1.6 V vs. RHE to achieve a current density of 85 mA cm−2 for OER, which are attributed to the enhanced conductivity and improved surface active sites facilitated by oxygen vacancies. With the accelerated hydrogen generation process and activated water oxidation reaction, MoO2 is demonstrated to be a suitable and stable bifunctional electrode for full water splitting, and the post-treatment process for oxygen vacancies also provides an effective strategy for improving electrocatalysis. [Display omitted]
doi_str_mv 10.1016/j.electacta.2020.136929
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Electrocatalytic water splitting, including hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), is an ideal method to produce hydrogen energy source. Stable electrocatalysts with good electrolytic activity are crucial for long-term water splitting. In this work, we show that MoO2 nanosheets can be grown directly on nickel foam substrate with oxygen vacancies decorated on the surface, acting as an excellent electrocatalyst for practical water splitting. In comparison to the pristine sample, the optimized MoO2, treated by 2% N2H4 solution for 20 min, exhibits a relatively low onset potential of −60 mV vs. reversible hydrogen electrode (RHE) for HER and a cell voltage of about 1.6 V vs. RHE to achieve a current density of 85 mA cm−2 for OER, which are attributed to the enhanced conductivity and improved surface active sites facilitated by oxygen vacancies. With the accelerated hydrogen generation process and activated water oxidation reaction, MoO2 is demonstrated to be a suitable and stable bifunctional electrode for full water splitting, and the post-treatment process for oxygen vacancies also provides an effective strategy for improving electrocatalysis. 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Electrocatalytic water splitting, including hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), is an ideal method to produce hydrogen energy source. Stable electrocatalysts with good electrolytic activity are crucial for long-term water splitting. In this work, we show that MoO2 nanosheets can be grown directly on nickel foam substrate with oxygen vacancies decorated on the surface, acting as an excellent electrocatalyst for practical water splitting. In comparison to the pristine sample, the optimized MoO2, treated by 2% N2H4 solution for 20 min, exhibits a relatively low onset potential of −60 mV vs. reversible hydrogen electrode (RHE) for HER and a cell voltage of about 1.6 V vs. RHE to achieve a current density of 85 mA cm−2 for OER, which are attributed to the enhanced conductivity and improved surface active sites facilitated by oxygen vacancies. With the accelerated hydrogen generation process and activated water oxidation reaction, MoO2 is demonstrated to be a suitable and stable bifunctional electrode for full water splitting, and the post-treatment process for oxygen vacancies also provides an effective strategy for improving electrocatalysis. 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subjects Electrocatalysts
Electrodes
HER
Hydrogen
Hydrogen evolution reactions
Hydrogen production
Hydrogen-based energy
Metal foams
Molybdenum oxides
MoO2
OER
Oxidation
Oxygen evolution reactions
Oxygen vacancy
Substrates
Vacancies
Water splitting
title Surface excited MoO2 to master full water splitting
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