Operando Bragg Coherent Diffraction Imaging of LiNi 0.8 Mn 0.1 Co 0.1 O 2 Primary Particles within Commercially Printed NMC811 Electrode Sheets

Due to complex degradation mechanisms, disparities between the theoretical and practical capacities of lithium-ion battery cathode materials persist. Specifically, Ni-rich chemistries such as LiNi Mn Co O (or NMC811) are one of the most promising choices for automotive applications; however, they co...

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Bibliographic Details
Published inACS nano Vol. 15; no. 1; pp. 1321 - 1330
Main Authors Estandarte, Ana Katrina C, Diao, Jiecheng, Llewellyn, Alice V, Jnawali, Anmol, Heenan, Thomas M M, Daemi, Sohrab R, Bailey, Josh J, Cipiccia, Silvia, Batey, Darren, Shi, Xiaowen, Rau, Christoph, Brett, Dan J L, Jervis, Rhodri, Robinson, Ian K, Shearing, Paul R
Format Journal Article
LanguageEnglish
Published United States 26.01.2021
Subjects
NMC811
synchrotron
electric vehicle
CDI
X-ray
operando
Li ion
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Summary:Due to complex degradation mechanisms, disparities between the theoretical and practical capacities of lithium-ion battery cathode materials persist. Specifically, Ni-rich chemistries such as LiNi Mn Co O (or NMC811) are one of the most promising choices for automotive applications; however, they continue to suffer severe degradation during operation that is poorly understood, thus challenging to mitigate. Here we use Bragg coherent diffraction imaging for 4D analysis of these mechanisms by inspecting the individual crystals within primary particles at various states of charge (SoC). Although some crystals were relatively homogeneous, we consistently observed non-uniform distributions of inter- and intracrystal strain at all measured SoC. Pristine structures may already possess heterogeneities capable of triggering crystal splitting and subsequently particle cracking. During low-voltage charging (2.7-3.5 V), crystal splitting may still occur even during minimal bulk deintercalation activity; and during discharging, rotational effects within parallel domains appear to be the precursor for the nucleation of screw dislocations at the crystal core. Ultimately, this discovery of the central role of crystal grain splitting in the charge/discharge dynamics may have ramifications across length scales that affect macroscopic performance loss during real-world battery operation.
ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.0c08575