光催化
材料科学
催化作用
纳米材料
纳米颗粒
制氢
化学工程
氧化物
纳米技术
粒径
粒子(生态学)
氢
比表面积
球磨机
光催化分解水
可见光谱
带隙
化学还原
化学能
无机化学
航程(航空)
纳米
作者
Aadil Bathla,Adrien Moll,Nita Dragoe,David Bérardan,Diana Dragoé,Wahid Ullah,Mohamed Nawfal Ghazzal
标识
DOI:10.1021/acsanm.5c03119
摘要
The emergence of entropy-stabilized oxides has transformed the paradigm of functional materials design, in particular, for catalytic applications. However, the high-temperature treatments usually used for their synthesis lead to the formation of large particles with a small specific active surface and low photocatalytic efficiency. In this work, we use a top-down approach to downsize rock-salt entropy-stabilized oxide (Mg0.2Ni0.2Zn0.2Co0.2Li0.1Ga0.1)O particles to the nanometric scale using a mechanical ball-milling process. This two-step process is easily scalable and enables the synthesis of entropy-stabilized nanoparticles with well-controlled and easily tunable chemical composition. The particle sizes obtained under dry ball milling were in the range of 4–7 nm, with an increase in the specific surface area up to 6.6 m2 g–1. Besides, we observed a partial reduction of the cations during the ball-milling process, affecting the optical bandgap of the nanomaterials compared to the bulk material. Under optimal conditions, photocatalytic H2 generation reached 111 μmol.g–1 after 4 h of illumination in the presence of triethanolamine.
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