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Preintercalation Strategy in Manganese Oxides for Electrochemical Energy Storage: Review and Prospects

Qinghe Zhao, Aoye Song, Shouxiang Ding, Runzhi Qin, Yan-Hui Cui, Shuning Li, Feng Pan

2020Advanced Materials257 citationsDOI

Abstract

Abstract Manganese oxides (MnO 2 ) are promising cathode materials for various kinds of battery applications, including Li‐ion, Na‐ion, Mg‐ion, and Zn‐ion batteries, etc., due to their low‐cost and high‐capacity. However, the practical application of MnO 2 cathodes has been restricted by some critical issues including low electronic conductivity, low utilization of discharge depth, sluggish diffusion kinetics, and structural instability upon cycling. Preintercalation of ions/molecules into the crystal structure with/without structural reconstruction provides essential optimizations to alleviate these issues. Here, the intrinsic advantages and mechanisms of the preintercalation strategy in enhancing electronic conductivity, activating more active sites, promoting diffusion kinetics, and stabilizing the structural integrity of MnO 2 cathode materials are summarized. The current challenges related to the preintercalation strategy, along with prospects for the future research and development regarding its implementation in the design of high‐performance MnO 2 cathodes for the next‐generation batteries are also discussed.

Topics & Concepts

Materials scienceManganeseElectrochemistryElectrochemical energy storageEnergy storageNanotechnologyManganese oxideElectrochemical energy conversionMetallurgySupercapacitorElectrodePhysical chemistryPhysicsChemistryPower (physics)Quantum mechanicsAdvanced battery technologies researchSupercapacitor Materials and FabricationAdvancements in Battery Materials