Hengning Chen1,Zeyu Deng1,Pieremanuele Canepa1,2
National University of Singapore1,University of Houston2
Hengning Chen1,Zeyu Deng1,Pieremanuele Canepa1,2
National University of Singapore1,University of Houston2
Although all-solid-state batteries (ASSBs) exhibit great potential for providing high energy density and enhanced battery safety, the stability of electrode−electrolyte interfaces is still a serious challenge. Niobate and tantalate materials have been widely applied as coating materials to mitigate the interfacial reactivities in ASSBs, especially amorphous LiMO<sub>3</sub> (M=Nb or Ta) with high ionic conductivities and appreciable electronic resistance.<sup>1</sup> Compared with pure LiMO<sub>3</sub> (M=Nb or Ta), partially-crystallized Li-Nb-Ta oxides were found to show even higher ionic conductivity and higher permittivity, which can be more effective for fast charge-transfer reactions at the cathode/electrolyte interfaces in ASSBs.<sup>2</sup> However, the mechanism behind Nb/Ta mixing and the improved properties needs to be further understood.<br/><br/>Leveraging a combination of density functional theory, cluster expansion formalism, grand canonical Monte Carlo (gcMC) simulations, and machine-learned molecular dynamics, we reveal the phase transition nature of LiTa<sub>1-x</sub>Nb<sub>x</sub>O<sub>3</sub> and the improved Li-ion conduction properties brought by Nb/Ta mixing. As studied in our previous work, the crystalline Li-M-O coating contains mixtures of LiMO<sub>3</sub> and Li<sub>3</sub>MO<sub>4</sub>, and we extend the mixing study into Li<sub>3</sub>MO<sub>4 </sub>as well.<sup>3</sup> Our investigation of the phase behavior and the structure-property relationships in the Li-Nb-Ta oxides helps to develop more suitable synthesis protocols to maximize the functional properties of these coating materials.<br/><br/>References:<br/>1. Glass, A. M., Nassau, K. & Negran, T. J. Ionic conductivity of quenched alkali niobate and tantalate glasses. <i>J. Appl. Phys.</i> <b>49</b>, 4808–4811 (1978).<br/>2. Yada, C. <i>et al.</i> A High-Throughput Approach Developing Lithium-Niobium-Tantalum Oxides as Electrolyte/Cathode Interlayers for High-Voltage All-Solid-State Lithium Batteries. <i>J. Electrochem. Soc.</i> <b>162</b>, 722–726 (2015).<br/>3. Chen, H., Deng, Z., Li, Y. & Canepa, P. On the Active Components in Crystalline Li-Nb-O and Li-Ta-O Coatings from First Principles. <i>Chem. Mater.</i> <b>35</b>, 5657–5670 (2023).