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Electronic Cloud Topology‐Driven Electrostatic Decoupling: To Suppress High‐Voltage Parasitic Reactions of Phosphate Cathode in Sodium‐Ion Batteries

Heng Zhang, Xiaotong Wang, Wen‐Yu Qian, Zhen‐Yi Gu, Yong‐Li Heng, Yan Liu, Xinru Zhang, Xin‐Yi Zhang, Hua Zhong, Ning Yu, Dai‐Huo Liu, Xing‐Long Wu

2025Angewandte Chemie International Edition9 citationsDOI

Abstract

Abstract The polyanionic structure cathodes with synergistic Mn/V redox couples enables high‐voltage platform and delivers considerable theoretical energy density in sodium‐ion battery. However, achieving stable and reversible high‐voltage redox reactions remain challenging due to the inactivation of redox couples during discharge. Herein, we found that coupled redox behavior triggered by orbitals with similar energy levels leads to high‐voltage irreversibility and parasitic reactions. To overcome this, we propose a strategy of adjusting the electron cloud topology by altering the electrostatic field, thereby changing the orbital energy gap between the t 2g state of V and the e g state of Mn, effectively decoupling the electrochemical reactions. As a model system, the Na 3.5 MnV 0.5 Ti 0.5 (PO 4 ) 3 (NMVTP) cathode significantly stabilizes the high‐voltage Mn 4+/3+ and V 5+/4+ pairs, and increases the reversible capacity from 99.41 to 123.9 mAh g −1 . This strategy opens new paths for developing high‐energy density batteries through orbital bandgap modification.

Topics & Concepts

Decoupling (probability)RedoxCathodeElectrochemistryTopology (electrical circuits)IonVoltageBattery (electricity)AnodeChemistryNanotechnologyMaterials scienceChemical physicsOptoelectronicsElectrodeElectrical engineeringInorganic chemistryPhysicsPhysical chemistryControl engineeringOrganic chemistryQuantum mechanicsPower (physics)EngineeringAdvancements in Battery MaterialsAdvanced Memory and Neural ComputingExtraction and Separation Processes