Lin Gaoxin, Ju Qiangjian, Liu Lijia, Guo Xuyun, Zhu Ye, Zhang Zhuang, Zhao Chendong, Wan Yingjie, Yang Minghui, Huang Fuqiang, Wang Jiacheng
State Key Lab of High Performance Ceramics and Superfine Microstructure, Shanghai Institute of Ceramics, Chinese Academy of Sciences, Shanghai 201899, China.
Center of Materials Science and Optoelectronics Engineering, University of Chinese Academy of Sciences, Beijing 100049, China.
ACS Nano. 2022 Jun 28;16(6):9920-9928. doi: 10.1021/acsnano.2c04513. Epub 2022 Jun 17.
Defect engineering provides a promising approach for optimizing the trade-off between support structures and active nanoparticles in heterojunction nanostructures, manifesting efficient synergy in advanced catalysis. Herein, a high density of distorted lattices and defects are successfully formed in bronze TiO through caging alkali-metal Na cations in open voids (Na-TiO(B)), which could efficiently cohere nanoparticulate electrocatalysts toward alkaline hydrogen evolution reaction (HER). The RuMo bimetallic nanoparticles could directionally anchor on Na-TiO(B) with a certain angle of ∼22° due to elimination of the lattice mismatch, thus promoting uniform dispersion and small sizing of supported nanoparticles. Moreover, caging Na ions could significantly enhance the hydrophilicity of the substrate in RuMo/Na-TiO(B), leading to the strengthening synergy of water dissociation and hydrogen desorption. As expected, this Na-caged nanocomposite catalyst rich with structural perturbations manifests a 6.4-fold turnover frequency (TOF) increase compared to Pt/C. The study provides a paradigm for designing stable nano-heterojunction catalysts with lattice-distorted substrates by caging cations toward advanced electrocatalytic transformations.
缺陷工程为优化异质结纳米结构中支撑结构与活性纳米粒子之间的权衡提供了一种很有前景的方法,在先进催化中表现出高效的协同作用。在此,通过将碱金属Na阳离子捕获在开放空隙中(Na-TiO(B)),在青铜TiO中成功形成了高密度的畸变晶格和缺陷,这可以有效地使纳米颗粒电催化剂凝聚以用于碱性析氢反应(HER)。由于消除了晶格失配,RuMo双金属纳米粒子可以以约22°的特定角度定向锚定在Na-TiO(B)上,从而促进负载纳米粒子的均匀分散和小尺寸化。此外,捕获Na离子可以显著提高RuMo/Na-TiO(B)中基底的亲水性,从而增强水离解和氢脱附的协同作用。正如预期的那样,这种富含结构扰动的Na捕获纳米复合催化剂的周转频率(TOF)比Pt/C提高了6.4倍。该研究为通过捕获阳离子设计具有晶格畸变基底的稳定纳米异质结催化剂以实现先进的电催化转化提供了一个范例。
