材料科学
光电流
级联
电荷(物理)
光电子学
钴
光电效应
同步辐射
载流子
化学物理
吸收(声学)
工作职能
Atom(片上系统)
纳米技术
光谱学
工作(物理)
有效核电荷
吸收光谱法
电子结构
超快激光光谱学
同步加速器
纳米颗粒
动力学
作者
Wenwen Ding,Haihan Yu,Junling Yin,Shenguang Ge,Jinghua Yu,Chaomin Gao
标识
DOI:10.1002/adfm.202518134
摘要
Abstract Single‐atom materials (SAMs), which are characterized by unique electronic structures and unsaturated coordination environments, exhibit maximum atomic utilization efficiency and exceptional reactivity, thus offering an advanced atomic‐level strategy to mitigate sluggish charge transfer kinetics that severely affect photoelectrochemical (PEC) responses. Herein, a cobalt single atom is employed to construct N─Co─O charge transfer bridges (termed Co‐ACTB) to facilitate charge separation in ZnIn 2 S 4 and MIL‐125‐NH 2 (ZIS/MIL) Z‐scheme heterojunctions. Synchrotron radiation X‐ray absorption spectroscopy suggests the successful construction of Co‐ACTB by elucidating the atomic configuration and local coordination characteristics of Co species. Theoretical calculations reveal coexisting regions of charge depletion and accumulation enveloping N─Co─O configuration, confirming their function as effective charge‐transfer channels. Co‐ACTB obviously strengthen charge transfer and enhance photoelectric properties. Consequently, ZIS/Co/MIL achieves a peak photocurrent of −349.85 µA cm −2 , representing 9.6‐fold and 162.7‐fold enhancements over those of ZIS/MIL and ZIS, respectively. Furthermore, a template reconstruction‐mediated bidirectional cascade rolling circle amplification strategy is integrated with a Co‐ACTB‐based photoelectrode to afford a sensitive PEC sensing platform, exhibiting a linear response ranging from 0.1 fM to 10 n m with a detection limit of 0.34 fM. This work provides novel insights into utilization of SAMs to enhance carrier separation within heterojunctions, thereby enhancing PEC sensing performance.
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