纳米棒
阳极
氧化物
异质结
催化作用
化学工程
耐久性
化学
析氧
纳米纤维
复合数
多孔性
纳米技术
静电纺丝
电化学
阳极氧化
钙钛矿(结构)
纳米线
氧气
材料科学
作者
Bingzhang Zhang,Chaochao Dun,Jiashun Liang,Sooyeon Hwang,Jiamao Zheng,Chun-Wai Chang,Micah Hickethier,Qiang Sun,Fan Yang,Xu Feng,Zhenxing Feng,Guofeng Wang,Gang Wu
摘要
Developing ultralow-Ir anode catalysts is desperately needed for proton-exchange-membrane water electrolysis, which requires high activity and adequate stability for the challenging acidic oxygen-evolution reaction. Here, we report a Ti–Zr composite electrospun oxide (ESO) nanorod support that enables high-performance ultralow-Ir anodes. The Zr-containing Ti oxide heterostructures are effective in stabilizing anatase-rich TiO 2, tuning the local oxygen-coordination environment, and strengthening the interfacial anchoring of IrO x under acidic anodic conditions. The electrospun porous nanorod network further creates an open, mechanically coherent catalyst layer, thereby improving Ir utilization, ionomer penetration, and mass transport in the ultralow-Ir anode. At a loading of 0.2 mg Ir cm –2, the optimized Ir/TiZr 20 -ESO anode delivers a mass activity of 0.99 A mg Ir –1 at 1.45 V, more than 40 times higher than a commercial TiO 2 -supported IrO 2 catalyst. The anode presents compelling performance and durability, achieving 3.0 and 4.0 A cm –2 at 1.75 and 1.83 V, respectively, and sustaining 2000 h of operation at 2.0 A cm –2 . Accelerated stress tests up to 525 h over 31,500 cycles also confirm promising long-term durability under dynamic conditions, demonstrating an insignificant decay of 0.4 μV per cycle. Theoretical calculations elucidate that the Ti–Zr oxide heterostructure can suppress Ti demetalation and strengthen IrO 2 interfacial binding, rationalizing the improved long-term durability of the ESO-supported ultralow-Ir anode.
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