Litcius/Paper detail

Deep-Learning Aided Atomic-Scale Phase Segmentation toward Diagnosing Complex Oxide Cathodes for Lithium-Ion Batteries

Dong Zhu, Chunyang Wang, Peichao Zou, Rui Zhang, Shefang Wang, Bohang Song, Xiaoyu Yang, Ke-Bin Low, Huolin L. Xin

2023Nano Letters20 citationsDOI

Abstract

Phase transformation─a universal phenomenon in materials─plays a key role in determining their properties. Resolving complex phase domains in materials is critical to fostering a new fundamental understanding that facilitates new material development. So far, although conventional classification strategies such as order-parameter methods have been developed to distinguish remarkably disparate phases, highly accurate and efficient phase segmentation for material systems composed of multiphases remains unavailable. Here, by coupling hard-attention-enhanced U-Net network and geometry simulation with atomic-resolution transmission electron microscopy, we successfully developed a deep-learning tool enabling automated atom-by-atom phase segmentation of intertwined phase domains in technologically important cathode materials for lithium-ion batteries. The new strategy outperforms traditional methods and quantitatively elucidates the correlation between the multiple phases formed during battery operation. Our work demonstrates how deep learning can be employed to foster an in-depth understanding of phase transformation-related key issues in complex materials.

Topics & Concepts

Atomic unitsPhase (matter)CathodeTransformation (genetics)Materials scienceSegmentationIonLithium (medication)Computer scienceDeep learningScale (ratio)Atom (system on chip)Battery (electricity)NanotechnologyArtificial intelligenceChemistryPhysicsElectrical engineeringPower (physics)EngineeringQuantum mechanicsEndocrinologyOrganic chemistryEmbedded systemBiochemistryGeneMedicineMachine Learning in Materials ScienceElectron and X-Ray Spectroscopy TechniquesAdvanced Electron Microscopy Techniques and Applications