Engineering LDH-Derived LiCoMnO4 Spinel/MXene Heterostructures via a Dual-Tuning Strategy for Efficient Lithium Extraction from Low-Grade Brines

材料科学 插层(化学) 化学工程 吸附 X射线光电子能谱 电极 异质结 锂(药物) 电化学 无机化学 结构稳定性 密度泛函理论 扩散 动力学 纳米技术 水溶液 选择性吸附 晶体结构 电子衍射
作者
Tianqin Huang,Pengrui Sun,Ruiqi Yong,Yan Wang,Ying Zhao,Chuhan Huang,Wei Zhou,Lifeng Ding,Lu Guo,Xianfen Wang,Meng Ding
出处
期刊:Green Energy & Environment [KeAi]
标识
DOI:10.1016/j.gee.2026.03.019
摘要

Electrochemical lithium extraction from low-grade salt lake brines is a sustainable approach to reliable and cost-efficient lithium supply, yet it is hindered by sluggish diffusion kinetics and the severe interference from competing Mg 2+ ions. This study proposes a “dual-tuned” strategy to engineer a high-performance electrode by simultaneously optimizing the intrinsic crystal architecture and the extrinsic conductive network. First, nanosized LiCoMnO 4 (LCMO) spinels (∼100 nm) were synthesized via a topotactic transformation from ultrathin Co-Mn-layered double hydroxide (LDH) precursors, effectively shortening ion diffusion paths. Second, these nano-spinels were integrated with Ti 3 C 2 T x MXene nanosheets to construct a 3D conductive framework that accelerates electron transport. The optimized 50%LCMO/MXene electrode achieved a superior lithium adsorption capacity of 188.55 mg g –1 (4.45 mmol g –1 ) and remarkable stability (87.6% retention over 200 cycles). Mechanistic investigations via ex - situ XPS and DFT revealed a distinct adsorption pathway: Li + undergoes bulk intercalation driven by reversible lattice volume evolution, while Mg 2+ is restricted to surface accumulation. Moreover, DFT analysis reveals that the Mn environment remains remarkably rigid. This local electronic rigidity minimizes the Jahn-Teller effect and Mn dissolution, providing a fundamental structural explanation for the electrode’s enhanced durability. A dual-tuned LCMO@MXene heterostructure is synthesized via topotactic transformation for selective lithium recovery. The material exhibits a divergent adsorption pathway where bulk lithium intercalation is facilitated by a lower kinetic barrier, while structural stability is maintained through the local electronic rigidity of the Mn 3d orbitals, effectively suppressing Jahn-Teller distortion and Mn dissolution. • Nanosized spinel LiCoMnO 4 was derived from Co-Mn-LDH via topotactic transformation. • Dual-tuned LCMO@MXene electrodes for faster electrochemical lithium extraction. • Superior lithium extraction capacity of 188.55 mg g –1 with high energy efficiency. • Excellent stability (87.6% retention over 200 cycles) due to suppressed Jahn-Teller effect. • DFT and ex-situ analysis reveal relationship between redox and electronic rigidity.
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