Spontaneous passivation on high-voltage manganese-based layered oxide cathodes via Selective surface doping for potassium-ion batteries

IF 13.3 1区工程技术 Q1 ENGINEERING, CHEMICAL

Chemical Engineering Journal Pub Date : 2025-02-09 DOI:10.1016/j.cej.2025.160414

Zhengkui Li, Wei Xiao, Huaming Qian, Wengang Lv, Kailin Zhang, Mengnan Wu, Zhengxi Hou, Jiaxu Yang, Xintian Li, Menglin Zhang, Xiaohui Zhang, Chong Xie, Huijuan Yang, Jingjing Wang, Xifei Li

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Abstract

The resourceful manganese-based layered oxide cathodes, benefitting from a high redox activity in Mn^4+/3+ couple and a superior reaction kinetics in prismatic configuration, presented desirable energy densities and rate capabilities in low-cost potassium-ion batteries (PIBs). Unfortunately, their harsh depotassiation/potassiation processes at high voltages still confronted notorious lattice distortions and irreversible phase transformations with interfacial side reactions, resulting in rapid capacity degradations. Herein, a novel surface-doping strategy, involving an atomic layer deposition and a subsequent annealing treatment, was adopted to address the structural/interfacial instabilities of P3-type K_0.5MnO₂ cathode. Theoretically, the Zn²⁺ derived from ZnO with a lowest diffusion barrier among different cations in K_0.5MnO₂ was primarily selected to reconstruct thermodynamically stable passivation surfaces on unstable cathode materials. Interestingly, the gradient integrations of highly electronegative Zn²⁺ into cathodes without changing phases/morphologies could enrich labile surfaces with intrinsically stable Mn⁴⁺ through charge balance and ameliorate structural/interfacial stabilities upon cycling. Between 4.2 ∼ 1.5 V, the discharging capacity retentions at 50 mA g⁻¹ over 50 cycles and 100 mA g⁻¹ over 100 cycles can be significantly enhanced from 37.5 % and 26.7 % for pristine K_0.5MnO₂ to 70.2 % and 51.3 % for K_0.5MnO₂-Zn-30C, respectively. Simultaneously, the optimized K_0.5MnO₂-Zn-30C cathode could still retain an outstanding rate capability of 69 mAh g⁻¹ at 500 mA g⁻¹, outperforming a corresponding parameter of 50 mAh g⁻¹ for pristine K_0.5MnO₂ cathode. Importantly, the conductive and robust passivation layers on K_0.5MnO₂ could boost the solid-state reaction kinetics upon K⁺ uptakes/removals, suppress the irreversible phase formations during cycling, and stabilize the deformable layered structures in the whole voltages. This innovative research on interfacial reconstructions of unstable layered oxides could enlighten the surface modifications on high-voltage cathodes for cost-effective and high-energy PIBs.

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资源丰富的锰基层状氧化物阴极，得益于 Mn4+/3+ 对偶的高氧化还原活性和棱柱构型的卓越反应动力学，在低成本钾离子电池（PIB）中呈现出理想的能量密度和速率能力。遗憾的是，它们在高电压下的苛刻去钝化/钝化过程仍然面临着众所周知的晶格畸变和不可逆相变以及界面副反应，从而导致容量迅速下降。本文采用了一种新颖的表面掺杂策略，包括原子层沉积和随后的退火处理，以解决 P3 型 K0.5MnO2 阴极的结构/界面不稳定性问题。理论上，在 K0.5MnO2 的不同阳离子中，ZnO 衍生物 Zn2+ 的扩散阻力最低，因此主要选择 Zn2+ 在不稳定的阴极材料上重建热力学稳定的钝化表面。有趣的是，在不改变相/形态的情况下，将高电负性 Zn2+ 梯度整合到阴极中，可以通过电荷平衡用内在稳定的 Mn4+ 丰富易损表面，并在循环过程中改善结构/界面稳定性。在 4.2 ∼ 1.5 V 之间，50 mA g-1 循环 50 次和 100 mA g-1 循环 100 次的放电容量保持率分别从原始 K0.5MnO2 的 37.5% 和 26.7% 显著提高到 K0.5MnO2-Zn-30C 的 70.2% 和 51.3%。同时，优化的 K0.5MnO2-Zn-30C 阴极在 500 mA g-1 的条件下仍能保持 69 mAh g-1 的出色速率能力，优于原始 K0.5MnO2 阴极 50 mAh g-1 的相应参数。重要的是，K0.5MnO2 上导电且坚固的钝化层可在 K+吸收/去除时促进固态反应动力学，抑制循环过程中不可逆相的形成，并在整个电压下稳定可变形的层状结构。这项关于不稳定层状氧化物界面重构的创新性研究可为实现高性价比和高能量 PIB 的高压阴极表面改性提供启示。

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来源期刊

Chemical Engineering Journal 工程技术-工程：化工

CiteScore

21.70

自引率

9.30%

发文量

6781

审稿时长

2.4 months

期刊介绍： The Chemical Engineering Journal is an international research journal that invites contributions of original and novel fundamental research. It aims to provide an international platform for presenting original fundamental research, interpretative reviews, and discussions on new developments in chemical engineering. The journal welcomes papers that describe novel theory and its practical application, as well as those that demonstrate the transfer of techniques from other disciplines. It also welcomes reports on carefully conducted experimental work that is soundly interpreted. The main focus of the journal is on original and rigorous research results that have broad significance. The Catalysis section within the Chemical Engineering Journal focuses specifically on Experimental and Theoretical studies in the fields of heterogeneous catalysis, molecular catalysis, and biocatalysis. These studies have industrial impact on various sectors such as chemicals, energy, materials, foods, healthcare, and environmental protection.