Author
Listed:
- Kai He
(Brookhaven National Laboratory)
- Sen Zhang
(University of Pennsylvania)
- Jing Li
(Brookhaven National Laboratory)
- Xiqian Yu
(Brookhaven National Laboratory)
- Qingping Meng
(Brookhaven National Laboratory)
- Yizhou Zhu
(University of Maryland)
- Enyuan Hu
(Brookhaven National Laboratory)
- Ke Sun
(Brookhaven National Laboratory)
- Hongseok Yun
(University of Pennsylvania)
- Xiao-Qing Yang
(Brookhaven National Laboratory)
- Yimei Zhu
(Brookhaven National Laboratory)
- Hong Gan
(Brookhaven National Laboratory)
- Yifei Mo
(University of Maryland)
- Eric A. Stach
(Brookhaven National Laboratory)
- Christopher B. Murray
(University of Pennsylvania)
- Dong Su
(Brookhaven National Laboratory)
Abstract
Spinel transition metal oxides are important electrode materials for lithium-ion batteries, whose lithiation undergoes a two-step reaction, whereby intercalation and conversion occur in a sequential manner. These two reactions are known to have distinct reaction dynamics, but it is unclear how their kinetics affects the overall electrochemical response. Here we explore the lithiation of nanosized magnetite by employing a strain-sensitive, bright-field scanning transmission electron microscopy approach. This method allows direct, real-time, high-resolution visualization of how lithiation proceeds along specific reaction pathways. We find that the initial intercalation process follows a two-phase reaction sequence, whereas further lithiation leads to the coexistence of three distinct phases within single nanoparticles, which has not been previously reported to the best of our knowledge. We use phase-field theory to model and describe these non-equilibrium reaction pathways, and to directly correlate the observed phase evolution with the battery’s discharge performance.
Suggested Citation
Kai He & Sen Zhang & Jing Li & Xiqian Yu & Qingping Meng & Yizhou Zhu & Enyuan Hu & Ke Sun & Hongseok Yun & Xiao-Qing Yang & Yimei Zhu & Hong Gan & Yifei Mo & Eric A. Stach & Christopher B. Murray & D, 2016.
"Visualizing non-equilibrium lithiation of spinel oxide via in situ transmission electron microscopy,"
Nature Communications, Nature, vol. 7(1), pages 1-9, September.
Handle:
RePEc:nat:natcom:v:7:y:2016:i:1:d:10.1038_ncomms11441
DOI: 10.1038/ncomms11441
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