揭示 PEO-Li6PS5Cl 相间的反应性和锂离子交换:固态核磁共振的启示

Pedram Ghorbanzade, Arianna Pesce, Michel Armand, Kerman Gómez, Shanmukaraj Devaraj, Pedro López-Aranguren, Juan Miguel López del Amo
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摘要

Li6PS5Cl (LPSCl) 仲化合物具有很高的室温离子电导率(1 mS cm-1),是最有前途的固体电解质之一。然而,它们对锂金属的化学性质不稳定,影响了其长期循环性。使用 PEO-LiTFSI 作为复合电解质的中间层或基质,是解决这一问题的可行策略。然而,PEO-LiTFSI 和 LPSCl 的相间关系还需要进一步详细研究。这项研究利用固态核磁共振探索了这些相之间的界面反应。结果表明,PEO 有利于与 LPSCl 中的 LiCl 和 Li3PS4 形成复合物,导致相间材料的局部流动性受限,从而阻碍了离子的传输。虽然添加 Br 作为掺杂剂可以通过诱导无序和产生锂空位来改善 LPSCl 的离子导电性,但它会使 LPSCl 更容易受到 PEO 的影响,并增加界面反应的程度。6Li-6Li EXSY 实验证明了 PEO 和 LPSCl 之间的自发锂离子交换,但这种交换受到 PEO-LPSCl 相间反应产物的严重阻碍,原因在于它们的局部动力学缓慢。这项研究揭示了 PEO-LiTFSI 与硫化物 Argyrodite 之间复杂的界面相互作用,为设计新一代电化学设备的固体电解质提供了启示。
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Unveiling the Reactivity and the Li-Ion Exchange at the PEO-Li6PS5Cl Interphase: Insights from Solid-State NMR
Li6PS5Cl (LPSCl) argyrodites offer high room temperature ionic conductivity (>1 mS cm−1) and are among the most promising solid electrolytes. However, their chemical instability against Li metal compromises the long-term cyclability. Using PEO-LiTFSI as an interlayer or as a matrix for composite electrolytes is a promising strategy to address this issue. Nevertheless, the interphase of PEO-LiTFSI and LPSCl requires further detailed investigations. This work explores the interfacial reactions between these phases using solid-state nuclear magnetic resonance. Results show that PEO facilitates the formation of a complex with LiCl and Li3PS4 from LPSCl, resulting in an interphase material with limited local mobility, thus impeding ion transport. Although the addition of Br as a dopant can improve the ionic conductivity of LPSCl by inducing disorder and generating the Li vacancies, it makes the LPSCl more susceptible to PEO and increases the extent of the interfacial reaction. 6Li–6Li EXSY experiments demonstrate spontaneous Li-ion exchange between the PEO and the LPSCl, yet this exchange is significantly hindered by reaction products within the PEO-LPSCl interphase, attributable to their sluggish local dynamics. This study sheds light on the complex interfacial interaction between PEO-LiTFSI and sulfide argyrodite, providing insights into designing solid electrolytes for the new generation of electrochemical devices.
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