Kim Sunmin, Kim Minji, Ku Miju, Park Junghum, Lee Jonghyuk, Kim Young-Beom
Department of Mechanical Convergence Engineering, Hanyang University, 222 Wangsimni-ro, Seongdong-gu, Seoul 04763, Republic of Korea.
Department of Battery Engineering, Hanyang University, 222 Wangshimni-ro, Seongdong-gu, Seoul 04763, Republic of Korea.
ACS Nano. 2024 Sep 10;18(36):25096-25106. doi: 10.1021/acsnano.4c06720. Epub 2024 Aug 27.
This study focused on addressing the challenges associated with the incompatibility between sulfide solid electrolytes and Ni-rich cathode active materials (CAMs) in all-solid-state lithium-ion batteries. To resolve these issues, protective layers have been explored for Ni-rich materials. Lithium lanthanum titanate (LLTO), a perovskite-type material, is recognized for its excellent chemical stability and ionic conductivity, which render it a potential protective layer in CAMs. However, traditional methods of achieving the perovskite structure involve temperatures exceeding 700 °C, resulting in challenges such as LLTO agglomeration, secondary phase formation between LLTO and CAM, and cation mixing within the CAM. In this study, a rapid technique known as flash-light sintering (FLS) was employed to fabricate a uniform and pure perovskite protective layer without inducing cation mixing within the CAM. The LLTO-coated LiNiCoMnO (NCM811) with FLS treatment demonstrated minimal cation mixing and formed a fully covered dense layer. This resulted in a high initial capacity and effectively addressed the incompatibility issues between the sulfide electrolytes and CAM. The rapid FLS method not only streamlines the fabrication of LLTO-coated NCM811 but also provides opportunities for its broader application to materials that were previously deemed impractical because of high sintering temperatures.
本研究聚焦于解决全固态锂离子电池中硫化物固体电解质与富镍正极活性材料(CAMs)不相容所带来的挑战。为解决这些问题,已对富镍材料的保护层展开探索。钛酸锂镧(LLTO),一种钙钛矿型材料,因其出色的化学稳定性和离子导电性而被认可,这使其成为CAMs中潜在的保护层。然而,实现钙钛矿结构的传统方法涉及超过700°C的温度,这导致了诸如LLTO团聚、LLTO与CAM之间形成第二相以及CAM内阳离子混合等挑战。在本研究中,一种名为闪光烧结(FLS)的快速技术被用于制备均匀且纯净的钙钛矿保护层,同时不会在CAM内引发阳离子混合。经过FLS处理的涂覆LLTO的LiNiCoMnO(NCM811)表现出最小的阳离子混合,并形成了完全覆盖的致密层。这带来了高初始容量,并有效解决了硫化物电解质与CAM之间的不相容问题。快速的FLS方法不仅简化了涂覆LLTO的NCM811的制备过程,还为其更广泛地应用于因烧结温度高而先前被认为不实用的材料提供了机会。
