Modulating the electronic interactions via heterostructure engineering for energy-saving hydrogen production at high current densities

被引:0
|
作者
Tan, Dongxing [1 ]
Yin, Xianfang [1 ]
Wang, Jing [1 ]
Zhang, Zixuan [1 ]
Zhu, Xiao [1 ]
Kang, Hengrui [1 ]
Feng, Yuanyuan [1 ]
机构
[1] Qufu Normal Univ, Sch Chem & Chem Engn, Key Lab Catalyt Convers & Clean Energy Univ Shando, Qufu 273165, Shandong, Peoples R China
来源
JOURNAL OF MATERIALS CHEMISTRY A | 2024年
基金
中国国家自然科学基金;
关键词
REDUCTION;
D O I
10.1039/d4ta07348g
中图分类号
O64 [物理化学(理论化学)、化学物理学];
学科分类号
070304 ; 081704 ;
摘要
Advanced alkaline hydrogen evolution reaction (HER) catalysts should exhibit a low water dissociation energy barrier and fast reaction kinetics. However, single-component transition metal catalysts typically show insufficient activation of water, leading to unsatisfactory electrocatalytic activity. Rationally modulating the composition and constructing heterogeneous interfaces can effectively regulate the interfacial electronic structure of catalysts, thereby improving the kinetics and catalytic activity of the alkaline HER. Herein, Ni0.2Mo0.8N/F,N-C@NF heterogeneous catalyst was prepared, demonstrating excellent alkaline HER activity (281 mV @ 1000 mA cm-2). Experimental results and density functional theory (DFT) calculations indicate that heterogeneous engineering can effectively modulate the surface charge structure of catalysts, enhancing the adsorption and activation of reactive intermediates. Simultaneously, heterogeneous engineering accelerates reaction kinetics by further reducing the energy barrier of the Tafel step. The Ni0.2Mo0.8N/F,N-C@NF catalyst also exhibits satisfactory catalytic activity towards the HER when integrated with a methanol oxidation reaction. This work provides an effective guide for the rational design of high-performance alkaline HER electrocatalysts for energy-saving hydrogen production.
引用
收藏
页码:267 / 274
页数:8
相关论文
共 50 条
  • [41] Replacing Oxygen Evolution with Hydrazine Oxidation at the Anode for Energy-Saving Electrolytic Hydrogen Production
    Wang, Jianmei
    Kong, Rongmei
    Asiri, Abdullah M.
    Sun, Xuping
    CHEMELECTROCHEM, 2017, 4 (03): : 481 - 484
  • [42] Energy-saving hydrogen production by water splitting coupling urea decomposition and oxidation reactions
    Xiao, Zehao
    Qian, Yinyin
    Tan, Tianhui
    Lu, Hongxiu
    Liu, Canhui
    Wang, Bowen
    Zhang, Qiang
    Sarwar, Muhammad Tariq
    Gao, Ruijie
    Tang, Aidong
    Yang, Huaming
    JOURNAL OF MATERIALS CHEMISTRY A, 2022, 11 (01) : 259 - 267
  • [43] Constructing Fe-Co2P/CeO2 heterostructure nanosheet arrays for attaining energy-saving hydrogen production in seawater
    Li, Rui-Qing
    Su, Hang
    Xie, Shui-Xiang
    Wan, Xiao-Yu
    Wang, Chang-Ming
    Zhang, Guang-Yu
    Ge, Ming-Zheng
    Dai, Jia-Mu
    Xue, Chao-Zhuang
    Li, Chao-Rong
    Cao, Jun
    Zhang, Wei
    RARE METALS, 2024, 43 (12) : 6426 - 6435
  • [44] Replacing Oxygen Evolution with Hydrazine Borane Oxidation for Energy-Saving Electrochemical Hydrogen Production
    Peng, Yefei
    Huang, Minsong
    Yang, Qifeng
    Xing, Zhiyuan
    Lu, Zhang-Hui
    INORGANIC CHEMISTRY, 2023, 62 (28) : 11056 - 11063
  • [45] PdOs bimetallene for energy-saving hydrogen production coupled with ethanol electro-oxidation
    Wang, Ziqiang
    Li, Min
    Xu, Shan
    Yu, Hongjie
    Deng, Kai
    Xu, You
    Wang, Hongjing
    Wang, Liang
    MATERIALS TODAY ENERGY, 2024, 40
  • [46] Recent progress with electrocatalysts for urea electrolysis in alkaline media for energy-saving hydrogen production
    Sun, Xiujuan
    Ding, Rui
    Catalysis Science and Technology, 2020, 10 (06): : 1567 - 1581
  • [47] High-Entropy Sulfide Catalyst Boosts Energy-Saving Electrochemical Sulfion Upgrading to Thiosulfate Coupled with Hydrogen Production
    Pei, Yuhou
    Li, Di
    Qiu, Chuntian
    Yan, Liang
    Li, Zongmiao
    Yu, Zexin
    Fang, Wenzhang
    Lu, Yingying
    Zhang, Bing
    ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2024, 63 (48)
  • [48] Hydroxyl vacancies triggered high methanol oxidation activity of monolayered layered double hydroxides for energy-saving hydrogen production
    Liu, Bin
    Wang, Xiao
    Wang, Suwen
    Peng, Hui-Qing
    Xiao, Tongyao
    Liu, Guihao
    Bai, Sha
    Zhao, Yufei
    Zhang, Wenjun
    Song, Yu-Fei
    MATERIALS TODAY ENERGY, 2022, 28
  • [49] Development of Co-N-C-Deposited Nickel Foam for Energy-Saving Hydrogen Production via Electrocatalytic Conversion of Glycerol
    Thi Phan, Nga Hang
    Ngoc Nguyen, Hoang Luong
    Huyen Nguyen, Thi Thanh
    Dao, My Uyen
    Le, Trung Hieu
    Tran, Thi Thanh Van
    Mai, Van-Hieu
    Truong-Le, Bich-Tram
    Nguyen Dinh, Minh Tuan
    Le, Van Quyet
    Nguyen, Chinh Chien
    Kim, Soo Young
    ENERGY & FUELS, 2025, 39 (08) : 3882 - 3890
  • [50] Energy-saving high-current high-voltage keys and phase modules on their basis
    Panacenko, M. V.
    Panacenko, N. M.
    Khvorost, V. Yu.
    ELECTRICAL ENGINEERING & ELECTROMECHANICS, 2007, (05) : 24 - +
12345