A 17.73 % Solar-To-Hydrogen Efficiency with Durably Active Catalyst in Stable Photovoltaic-Electrolysis Seawater System

被引:0
|
作者
Gao, Yong [1 ]
Xu, Yunyun [2 ]
Guo, Hu [3 ]
Li, Jingjing [1 ]
Ding, Lingling [1 ]
Wang, Tao [1 ]
He, Jianping [1 ]
Chang, Kun [1 ]
Wu, Zhong-Shuai [2 ]
机构
[1] Nanjing Univ Aeronaut & Astronaut, Coll Mat Sci & Technol, Ctr Hydrogenergy, Nanjing 210016, Peoples R China
[2] Chinese Acad Sci, Dalian Inst Chem Phys, State Key Lab Catalysis, Dalian 116023, Peoples R China
[3] Nanjing Univ Sci & Technol, Sch New Energy, Nanjing 214400, Peoples R China
来源
ANGEWANDTE CHEMIE-INTERNATIONAL EDITION | 2025年
基金
中国国家自然科学基金;
关键词
WATER; ELECTROCATALYSTS;
D O I
暂无
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
Developing durably active catalysts to tackle harsh voltage polarization and seawater corrosion is pivotal for efficient solar-to-hydrogen (STH) conversion, yet remains a challenge. We report a durably active catalyst of NiCr-layered double hydroxide (RuldsNiCr-LDH) with highly exposed Ni-O-Ru units, in which low-loading Ru (0.32 wt %) is locked precisely at defect lattice site (Rulds) by Ni and Cr. The Cr site electron equilibrium reservoir and Cl- repulsion by intercalated CO32- ensure the highly durable activity of Ni-O-Ru units. The RuldsNiCr-LDH & Vert;RuldsNiCr-LDH electrolyzer based on anion exchange membrane water electrolysis (AEM-WE) shows ultrastable seawater electrolysis at 1000 mA cm-2. Employing RuldsNiCr-LDH both as anode and cathode, a photovoltaic-electrolysis seawater system achieves a 17.73 % STH efficiency, corresponding photovoltaic-to-hydrogen (PVTH) efficiency is 72.37 %. Further, we elucidate the dynamic evolutionary mechanism involving the interfacial water dissociation-oxidation, establishing the correlation between the dynamic behavior of interfacial water with the kinetics, activity of RuldsNiCr-LDH catalytic water electrolysis. Our work is a breakthrough step for achieving economically scalable production of green hydrogen.
引用
收藏
页数:10
相关论文
共 41 条
  • [1] A 17.73% Solar-To-Hydrogen Efficiency with Durably Active Catalyst in Stable Photovoltaic-Electrolysis Seawater System
    Gao, Yong
    Xu, Yunyun
    Guo, Hu
    Li, Jingjing
    Ding, Lingling
    Wang, Tao
    He, Jianping
    Chang, Kun
    Wu, Zhong-Shuai
    ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2025, 64 (09)
  • [2] Solar water splitting by photovoltaic-electrolysis with a solar-to-hydrogen efficiency over 30%
    Jia, Jieyang
    Seitz, Linsey C.
    Benck, Jesse D.
    Huo, Yijie
    Chen, Yusi
    Ng, Jia Wei Desmond
    Bilir, Taner
    Harris, James S.
    Jaramillo, Thomas F.
    NATURE COMMUNICATIONS, 2016, 7
  • [3] Solar water splitting by photovoltaic-electrolysis with a solar-to-hydrogen efficiency over 30%
    Jieyang Jia
    Linsey C. Seitz
    Jesse D. Benck
    Yijie Huo
    Yusi Chen
    Jia Wei Desmond Ng
    Taner Bilir
    James S. Harris
    Thomas F. Jaramillo
    Nature Communications, 7
  • [4] A photovoltaic-electrolysis system with high solar-to-hydrogen efficiency under practical current densities
    Zhang, Qingran
    Shan, Yihao
    Pan, Jian
    Kumar, Priyank
    Keevers, Mark J.
    Lasich, John
    Kour, Gurpreet
    Daiyan, Rahman
    Perez-Wurf, Ivan
    Thomsen, Lars
    Cheong, Soshan
    Jiang, Junjie
    Wu, Kuang-Hsu
    Chiang, Chao-Lung
    Grayson, Kristian
    Green, Martin A.
    Amal, Rose
    Lu, Xunyu
    SCIENCE ADVANCES, 2025, 11 (09):
  • [5] Predicting efficiency of solar powered hydrogen generation using photovoltaic-electrolysis devices
    Gibson, Thomas L.
    Kelly, Nelson A.
    INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2010, 35 (03) : 900 - 911
  • [6] Natural light driven photovoltaic-electrolysis water splitting with 12.7% solar-to-hydrogen conversion efficiency using a two-electrode system grown with metal foam
    Si, Fangyuan
    Wei, Meng
    Li, Mingli
    Xie, Xiaoer
    Gao, Qiongzhi
    Cai, Xin
    Zhang, Shengsen
    Peng, Feng
    Fang, Yueping
    Yang, Siyuan
    JOURNAL OF POWER SOURCES, 2022, 538
  • [7] An Earth-Abundant Catalyst-Based Seawater Photoelectrolysis System with 17.9% Solar-to-Hydrogen Efficiency
    Hsu, Shao-Hui
    Miao, Jianwei
    Zhang, Liping
    Gao, Jiajian
    Wang, Hongming
    Tao, Huabing
    Hung, Sung-Fu
    Vasileff, Anthony
    Qiao, Shi Zhang
    Liu, Bin
    ADVANCED MATERIALS, 2018, 30 (18)
  • [8] Improved hydrogen production efficiency of a Photovoltaic-Electrolysis system with P&O Algorithm: A case study
    Zou, Long
    Shen, Qiuwan
    Yang, Guogang
    Li, Shian
    Huang, Naibao
    CHEMICAL PHYSICS LETTERS, 2023, 832
  • [9] Solar hydrogen production: a bottom-up analysis of different photovoltaic-electrolysis pathways
    Reuss, M.
    Reul, J.
    Grube, T.
    Langemann, M.
    Calnan, S.
    Robinius, M.
    Schlatmann, R.
    Rau, U.
    Stolten, D.
    SUSTAINABLE ENERGY & FUELS, 2019, 3 (03) : 801 - 813
  • [10] Printed Co3O4 film as an electrocatalyst for hydrogen production by a monolithic photovoltaic-electrolysis system
    Jeon, Hyo Sang
    Park, Wonil
    Kim, Jaehoon
    Kim, Honggon
    Kim, Woong
    Min, Byoung Koun
    INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2011, 36 (03) : 1924 - 1929
12345