具有本征抑氯性能的海水电解高活性持久析氧催化剂的设计

IF 9.9 2区材料科学 Q1 Engineering

Nano Materials Science Pub Date : 2024-08-01 DOI:10.1016/j.nanoms.2023.10.003

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引用次数: 0

摘要

由于析氧催化剂的组成复杂、副反应激烈，其活性低、耐久性差，阻碍了海水电解的高效进行。本文通过在MXene (V2CTx)改性Ni泡沫(NF)基体上沉积nife层状双氢氧化物(NiFe-LDH)构建了一种异质结构催化剂，简称为NiFe-LDH/V2CTx/NF。结果表明，由于V2CTx的固有负电荷特性，氯离子被拒绝进入nfe - ldh和V2CTx/NF底物之间的界面，从而赋予nfe - ldh /V2CTx/NF催化剂高耐腐蚀性和在500 mA cm - 2下110 h的持久稳定性。同时，V2CTx的二维结构和高导电性可以分别扩大电化学活性表面积和保证快速电荷转移，从而协同促进NiFe-LDH/V2CTx/NF在去离子水电解质(261 mV, 100 mA cm−2)和模拟海水电解质(241 mV, 100 mA cm−2)中的催化性能。本工作对析氧催化剂的制备具有指导意义，可促进海水电解的工业化。

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Design of highly active and durable oxygen evolution catalyst with intrinsic chlorine inhibition property for seawater electrolysis

High-efficiency seawater electrolysis is impeded by the low activity and low durability of oxygen evolution catalysts due to the complex composition and competitive side reactions in seawater. Herein, a heterogeneous-structured catalyst is constructed by depositing NiFe-layered double hydroxides (NiFe-LDH) on the substrate of MXene (V₂CT_x) modified Ni foam (NF), and abbreviated as NiFe-LDH/V₂CT_x/NF. As demonstrated, owing to the intrinsic negative charge characteristic of V₂CT_x, chlorine ions are denied entry to the interface between NiFe-LDH and V₂CT_x/NF substrate, thus endowing NiFe-LDH/V₂CT_x/NF catalyst with high corrosion resistance and durable stability for 110 h at 500 mA cm⁻². Meanwhile, the two-dimensional structure and high electrical conductivity of V₂CT_x can respectively enlarge the electrochemical active surface area and guarantee fast charge transfer, thereby synergistically promoting the catalytic performance of NiFe-LDH/V₂CT_x/NF in both deionized water electrolyte (261 mV at 100 mA cm⁻²) and simulated seawater electrolyte (241 mV at 100 mA cm⁻²). This work can guide the preparation of oxygen evolution catalysts and accelerate the industrialization of seawater electrolysis.

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来源期刊

Nano Materials Science Engineering-Mechanics of Materials

CiteScore

20.90

自引率

3.00%

发文量

294

审稿时长

9 weeks

期刊介绍： Nano Materials Science (NMS) is an international and interdisciplinary, open access, scholarly journal. NMS publishes peer-reviewed original articles and reviews on nanoscale material science and nanometer devices, with topics encompassing preparation and processing; high-throughput characterization; material performance evaluation and application of material characteristics such as the microstructure and properties of one-dimensional, two-dimensional, and three-dimensional nanostructured and nanofunctional materials; design, preparation, and processing techniques; and performance evaluation technology and nanometer device applications.