Litcius/Paper detail

Interface-Mediated Jahn–Teller Effect in a Structure-Reinforced LiMnO <sub>2</sub> Cathode

Hanghui Liu, Tao Shen, Xiaohui Zhu, Mei Yang, Yushuai Yao, Eric Jianfeng Cheng, Yue Zhao, H. C. Li, Shuang Li, Lin Gu, Hui Xia

2026Journal of the American Chemical Society5 citationsDOI

Abstract

Lithium manganese-rich oxides are promising cobalt-free cathodes, but their viability is plagued by cooperative Jahn–Teller (CJT) distortions of Mn 3+ ions. Conventional strategies only partially mitigate this instability without addressing its electronic origin. Herein, we demonstrate a paradigm of interfacial orbital ordering to suppress CJT distortions at its root. We construct a spinel-layered LiMnO 2 heterostructure with noncollinear JT ordering (SLNC-LMO) and benchmark it against a collinear analog. Atomic-resolution imaging confirms the near-orthogonal arrangement of MnO 6 octahedra across the interfaces. Combined with density functional theory calculations, we reveal that this noncollinear ordering introduces orbital geometric frustration, which drastically reduces the e g orbital splitting energy to 0.24 eV from 1.12 eV of the collinear structure. This near restoration of orbital degeneracy suppresses long-range distortion propagation and enhances interfacial cohesion. Consequently, the SLNC-LMO cathode delivers exceptional cycling stability, retaining 100% of its capacity after 500 cycles, far outperforming the collinear counterpart. This work establishes interfacial orbital engineering as a general design principle for stabilizing manganese-rich and other Jahn–Teller-active electrode materials.

Topics & Concepts

CathodeChemistryDistortion (music)Degeneracy (biology)ElectrodeDensity functional theoryHeterojunctionWork (physics)OctahedronCondensed matter physicsLithium (medication)Atomic orbitalOrbital overlapMolecular orbitalInstabilityChemical physicsNon-bonding orbitalMolecular physicsBenchmark (surveying)Electronic structureOptoelectronicsTaperingComputational physicsFragment molecular orbitalBlock (permutation group theory)Energy (signal processing)ElectrochemistryDegrees of freedom (physics and chemistry)NanotechnologyHybrid functionalAdvancements in Battery MaterialsGraphene research and applicationsAdvanced Battery Materials and Technologies