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   https://doi.org/10.1149/2.0201906jes  

   Phillips, William ; Karmiol, Zachary ; Chidambaram, Dev ( January 2019 , Journal of The Electrochemical Society)
2. Li 2.9 Fe 0.9 Zr 0.1 Cl 6 as Redox-Active Catholyte for Solid-State Li-Ion Batteries

   https://doi.org/10.1021/acs.chemmater.4c01385  

   Zhang, Guangxing ; Liu, Zhantao ; Ma, Yifan ; Pepas, Jakub ; Bai, Jianming ; Zhong, Hui ; Tang, Yuanzhi ; Chen, Hailong ( October 2024 , Chemistry of Materials)
3. Non-adiabatic quantum interference in the ultracold Li + LiNa → Li 2 + Na reaction

   https://doi.org/10.1039/d0cp05499b  

   Kendrick, Brian K. ; Li, Hui ; Li, Ming ; Kotochigova, Svetlana ; Croft, James F. ; Balakrishnan, Naduvalath ( March 2021 , Physical Chemistry Chemical Physics)

   null (Ed.)

   Electronically non-adiabatic effects play an important role in many chemical reactions. However, how these effects manifest in cold and ultracold chemistry remains largely unexplored. Here for the first time we present from first principles the non-adiabatic quantum dynamics of the reactive scattering between ultracold alkali-metal LiNa molecules and Li atoms. We show that non-adiabatic dynamics induces quantum interference effects that dramatically alter the ultracold rotationally resolved reaction rate coefficients. The interference effect arises from the conical intersection between the ground and an excited electronic state that is energetically accessible even for ultracold collisions. These unique interference effects might be exploited for quantum control applications such as a quantum molecular switch. The non-adiabatic dynamics are based on full-dimensional ab initio potential energy surfaces for the two electronic states that includes the non-adiabatic couplings and an accurate treatment of the long-range interactions. A statistical analysis of rotational populations of the Li 2 product reveals a Poisson distribution implying the underlying classical dynamics are chaotic. The Poisson distribution is robust and amenable to experimental verification and appears to be a universal property of ultracold reactions involving alkali metal dimers. 

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4. The Nature of Lithium Bonding in C 2 H 2 Li 2 , C 6 Li 6 , and Lithium Halide Dimers

   https://doi.org/10.1021/acs.organomet.9b00683  

   Liu, Yameng ; Peng, Bin ; Wang, Xiao ; Xie, Yaoming ; Schaefer, Henry F. ( November 2019 , Organometallics)
5. NASICON Li 1.2 Mg 0.1 Zr 1.9 (PO 4 ) 3 Solid Electrolyte for an All‐Solid‐State Li‐Metal Battery

   https://doi.org/10.1002/smtd.202000764  

   Zhou, Qiongyu ; Xu, Biyi ; Chien, Po‐Hsiu ; Li, Yutao ; Huang, Bing ; Wu, Nan ; Xu, Henghui ; Grundish, Nicholas S. ; Hu, Yan‐Yan ; Goodenough, John B. ( September 2020 , Small Methods)

   A thin solid electrolyte with a high Li⁺conductivity is used to separate the metallic lithium anode and the cathode in an all‐solid‐state Li‐metal battery. However, most solid Li‐ion electrolytes have a small electrochemical stability window, large interfacial resistance, and cannot block lithium‐dendrite growth when lithium is plated on charging of the cell. Mg²⁺stabilizes a rhombohedral NASICON‐structured solid electrolyte of the formula Li_1.2Mg_0.1Zr_1.9(PO₄)₃(LMZP). This solid electrolyte has Li‐ion conductivity two orders of magnitude higher at 25 °C than that of the triclinic LiZr₂(PO₄)₃.⁷Li and⁶Li NMR confirm the Li‐ions in two different crystallographic sites of the NASICON framework with 85% of the Li‐ions having a relatively higher mobility than the other 15%. The anode–electrolyte interface is further investigated with symmetric Li/LMZP/Li cell testing, while the cathode–electrolyte interface is explored with an all‐solid‐state Li/LMZP/LiFePO₄cell. The enhanced performance of these cells enabled by the Li_1.2Mg_0.1Zr_1.9(PO₄)₃solid electrolyte is stable upon repeated charge/discharge cycling.

    

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