• 综述 •
杜宇, 刘德培, 闫世成, 于涛, 邹志刚. 镍铁水滑石电催化氧析出研究进展[J]. 化学进展, 2020, 32(9): 1386-1401.
Yu Du, Depei Liu, Shicheng Yan, Tao Yu, Zhigang Zou. NiFe Layered Double Hydroxides for Oxygen Evolution Reaction[J]. Progress in Chemistry, 2020, 32(9): 1386-1401.
氧析出反应(Oxygen evolution reaction, OER)是电解水制氢、二氧化碳还原、二次金属-空气电池等能源储存和转化技术中的关键半反应。镍铁水滑石类材料(NiFe layered double hydroxide, NiFe-LDH)具有独特的层状结构、优异的催化性能和成本低廉等优点,是一类极具潜力的OER催化材料。但电导率低、活性位点暴露不充分等缺点也限制了其催化性能的进一步提高。本文综述了包括引入缺陷、片层剥离、元素掺杂、表面修饰和原位生长等针对NiFe-LDH的改性方法,这些方法能有效提升反应活性位点数量、增强导电性并促进反应动力学过程。最后,讨论了对NiFe-LDH改性中存在的问题以及对后续研究的展望。
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Catalyst | Currant density/mA·cm-2 | Overpotential/mV | Tafel slope/mV·dec-1 | Main method | ref |
---|---|---|---|---|---|
Engraved NiFe-LDH | 10 | 250 | 69 | Defects introducing | 33 |
NiFe-LDH-VFe | 10 | 245 | 70.0 | Defects introducing | 36 |
NiFe-LDH-VNi | 10 | 229 | 62.9 | Defects introducing | 36 |
v-NiFe-LDH | 10 | 370 | - | Defects introducing | 37 |
r-NiFe-LDH | 240 | 270 | - | Defects introducing | 38 |
FeNi8Co2 LDH | 10 | 220 | 42 | Elements doping | 39 |
Ni2CoⅢFe-LDH/N-GO | onset | 180 | 56.8 | Elements doping & In-situ growing | 40 |
Ni0.75Fe0.125V0.125-LDH/NF | 10 | 231 | 39.4 | Elements doping & In-situ growing | 41 |
NiFeCr-6∶2∶1@CP | 25 | 225 | 69 | Elements doping | 2 |
5.0%Ce-NiFe-LDH/CNT | 10 | 227 | 33 | Elements doping | 42 |
NiO/NiFe-LDH | 10 | 180 | 30 | Surface decorating | 43 |
NF@NiFe-LDH/CeO x | 10 | 280 | - | Surface decorating & In-situ growing | 44 |
FeOOH2nm/LDH | 10 | 173 | 27 | Surface decorating | 45 |
Au/NiFe-LDH | 10 | 237 | 36 | Surface decorating | 46 |
NiFe-LDH@NiCoP/NF | 10 | 220 | 48.6 | In-situ growing | 47 |
NiFe-LDH/NiCo2O4/NF | 50 | 290 | 53 | In-situ growing | 48 |
(Ni, Co)Se2/NiFe-LDH | 10 | 205 | 61 | In-situ growing | 49 |
NiFe-LDH-NS | 10 | 300 | 40 | Exfoliating | 11 |
PM-NiFe-LDH | 10 | 230 | 47 | Exfoliating | 50 |
NiFe-LDH-UF | 10 | 254 | 32 | Exfoliating | 51 |
NiFe-LDH-NS@DG 10 | 10 | 210 | 52 | Exfoliating & In-situ growing | 52 |
NiFe-LDH/RGO | 30 | 273 | 49 | Exfoliating & In-situ growing | 53 |
Methods | Advantages | Disadvantages |
---|---|---|
Defect introducing | Tuning electronic structure with the formation of edge, corner and defect sites | Aggregation |
Exfoliating | Increasing the exposure of active sites | Aggregation |
Element doping | Regulating the electronic structures and enhancing the intrinsic catalytic activity | Limited improvement in catalytic performance |
Surface decorating | Changing intrinsic electronic structure | A limited number of active sites |
In-situ growing | Preventing aggregation and the synergistic effect to enhance OER stability and activity | Limited amount of loading scales |
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