纳米笼
电催化剂
过电位
化学
电化学
电解质
溶解
催化作用
无机化学
过渡金属
纳米技术
化学工程
金属
电合成
协同催化
分解水
假电容
电极
蛋壳膜
氢
可逆氢电极
聚苯胺
氧化还原
析氧
作者
Fanqi Kong,Jinhan Li,Zhichen Hou,Fangming Liu,Meng Yao,Yue Li,Kuiming Liu,F. Q. Zhang,Miao Yu,Hujun Shen,Jianwei Li,Zhenhua Yan,Lifang Jiao,Jun Chen,Fangyi Cheng
摘要
Breaking the activity–stability trade-off remains a formidable challenge in the pursuit of nonprecious metal electrocatalysts for water splitting. Here, we report a programmable electrochemical assembly of wet-adhesive polydopamine (PDA) nanocages on Ni 4 Mo alloys to enhance the hydrogen evolution reaction (HER). We demonstrate that the catechol groups strongly coordinate with Ni/Mo active sites, reinforcing interfacial adhesion and suppressing metal dissolution under harsh electrochemical conditions. Benefiting from a porous rigid–flexible nanocage architecture, the Ni 4 Mo@PDA electrode operates stably for 3000 h at 500 mA cm –2 with a low HER overpotential of 125 mV in alkaline electrolyte and for over 500 h in anion exchange membrane water electrolyzers. First-principles calculations unravel the formation of a multisite catalytic network that reconfigures the interfacial energetics of HER intermediates through PDA-mediated Ni and Mo coordination. By leveraging biomimetic PDA nanocages, this study underscores the importance of interfacial buffering toward efficient and durable electrocatalysis on nonprecious alloys.
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