Operando Study of Mechanical Integrity of High-Volume Expansion Li-Ion Battery Anode Materials Coated by Al2O3

Xinwei Zhou, Argonne National Laboratory
Liliana Stan, Argonne National Laboratory
Dewen Hou, Boise State University
Yang Jin, Zhengzhou University
Hui Xiong, Boise State University
Likun Zhu, Indiana University Purdue University Indianapolis
Yuzi Liu, Argonne National Laboratory


Group IV elements and their oxides, such as Si, Ge, Sn and SiO have much higher theoretical capacity than commercial graphite anode. However, these materials undergo large volume change during cycling, resulting in severe structural degradation and capacity fading. Al2O3 coating is considered an approach to improve the mechanical stability of high-capacity anode materials. To understand the effect of Al2O3 coating directly, we monitored the morphology change of coated/uncoated Sn particles during cycling using operando focused ion beam–scanning electron microscopy. The results indicate that the Al2O3 coating provides local protection and reduces crack formation at the early stage of volume expansion. The 3 nm Al2O3 coating layer provides better protection than the 10 and 30 nm coating layer. Nevertheless, the Al2O3 coating is unable to prevent the pulverization at the later stage of cycling because of large volume expansion.