材料科学
电导率
电极
极化(电化学)
复合数
反演(地质)
光电子学
载流子
电阻率和电导率
扩散
图层(电子)
复合材料
工程物理
扩散阻挡层
纳米技术
化学工程
表面电导率
凝聚态物理
作者
Zhiyuan Zhang,Jiequn Liu,Luzhi Liu,Xueling Hu,Huijue Luo,Yan Su,Jishu Zeng,Zejun Jiang,Yanfang Wang,Fangping Wang,Zongkang Sun,Zhuokui Zhong,Shibao Tang,Zhengfang Tang,Xiangbing Cai,Shengkui Zhong,Renheng Wang
摘要
ABSTRACT Metal‐organic frameworks (MOFs) are rising stars for Li‐ion batteries (LIBs) electrodes. However, low conductivity of MOFs easily caused polarization and poor active site utilization. Here, an innovative electronic inversion layer (EIL) was proposed to guide the composite and interface design of MIL‐53(Fe) with Ti 3 C 2 T x , prompting a remarkable increase in the electrical conductivity of MIL‐53(Fe) from 4.94 × 10 −2 µS/cm to 46.65 mS/cm (30 MPa). This enhancement is attributed to the EIL activated by Ti 3 C 2 T x effectively shift the primary charge carriers from holes to high‐mobility electrons. Simultaneously, the localized EIL promoted the formation of a p–n junction and establishes a hole concentration gradient in MIL‐53(Fe)@Ti 3 C 2 T x , thereby accelerating lithium‐ion diffusion kinetics. Consequently, the MIL‐53(Fe)@Ti 3 C 2 T x delivered a superior capacity of 450.3 mAh/g at 1 A/g, and the possible retention of 94% capacity after 1000 cycles, exceeding those of the MIL‐53(Fe) and Ti 3 C 2 T x . This investigation into MXene‐activated EIL presents an innovative strategy and mechanism of universal significance for addressing the inherent conductivity challenges acted by a series of electrode materials, especially MOFs and COFs.
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