Size-dependent Kinetics During Non-equilibrium Lithiation of Nano-sized Zinc Ferrite

Overview

Journal Nat Commun

Specialty Biology

Date 2019 Jan 11

PMID 30626870

Citations 5

Authors

Jing Li

Qingping Meng

Yiman Zhang

Lele Peng

Guihua Yu

Amy C Marschilok

Lijun Wu

Dong Su

Kenneth J Takeuchi

Esther S Takeuchi

Yimei Zhu

Eric A Stach

Affiliations

Soon will be listed here.

Abstract

Spinel transition metal oxides (TMOs) have emerged as promising anode materials for lithium-ion batteries. It has been shown that reducing their particle size to nanoscale dimensions benefits overall electrochemical performance. Here, we use in situ transmission electron microscopy to probe the lithiation behavior of spinel ZnFeO as a function of particle size. We have found that ZnFeO undergoes an intercalation-to-conversion reaction sequence, with the initial intercalation process being size dependent. Larger ZnFeO particles (40 nm) follow a two-phase intercalation reaction. In contrast, a solid-solution transformation dominates the early stages of discharge when the particle size is about 6-9 nm. Using a thermodynamic analysis, we find that the size-dependent kinetics originate from the interfacial energy between the two phases. Furthermore, the conversion reaction in both large and small particles favors {111} planes and follows a core-shell reaction mode. These results elucidate the intrinsic mechanism that permits fast reaction kinetics in smaller nanoparticles.

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