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Boosting Manganese Selenide Anode for Superior Sodium-Ion Storage via Triggering α → β Phase Transition

Shaokun Chong, Ting Li, Shuangyan Qiao, Yi‐Chun Yang, Zhengqing Liu, Jing Yang, Hsing‐Yu Tuan, Guozhong Cao, Wei Huang

2024ACS Nano45 citationsDOI

Abstract

Sodium-ion batteries (SIBs) have been extensively studied owing to the abundance and low-price of Na resources. However, the infeasibility of graphite and silicon electrodes in sodium-ion storage makes it urgent to develop high-performance anode materials. Herein, α-MnSe nanorods derived from δ-MnO 2 (δ−α-MnSe) are constructed as anodes for SIBs. It is verified that α-MnSe will be transferred into β-MnSe after the initial Na-ion insertion/extraction, and δ−α-MnSe undergoes typical conversion mechanism using a Mn-ion for charge compensation in the subsequent charge–discharge process. First-principles calculations support that Na-ion migration in defect-free α-MnSe can drive the lattice distortion to phase transition (alpha → beta) in thermodynamics and dynamics. The formed β-MnSe with robust lattice structure and small Na-ion diffusion barrier boosts great structure stability and electrochemical kinetics. Hence, the δ−α-MnSe electrode contributes excellent rate capability and superior cyclic stability with long lifespan over 1000 cycles and low decay rate of 0.0267% per cycle. Na-ion full batteries with a high energy density of 281.2 Wh·kg –1 and outstanding cyclability demonstrate the applicability of δ−α-MnSe anode.

Topics & Concepts

AnodeMaterials scienceIonElectrochemistrySelenideManganeseSodiumElectrodeElectrolyteCathodeChemistryPhysical chemistrySeleniumMetallurgyOrganic chemistryAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced battery technologies research