Author:
Moradipour Fariba,Markert Andreas,Rudszuck Thomas,Röttgen Niklas,Dück Gerald,Finsterbusch Martin,Gerbig Felix,Nirschl Hermann,Guthausen Gisela
Abstract
Charge transfer and mobility are essential for electrochemical processes in batteries, which need to be understood in detail for optimization, especially in the case of all-solid-state batteries. Wide line NMR is well-known in solid-state NMR and allows the quantification of ion mobility in ordered crystalline and amorphous structures. Temperature-dependent <sup>23</sup>Na-NMR is sensitive to ion mobility via longitudinal relaxation, but also via line analysis and transverse relaxation. As <sup>23</sup>Na is a spin 3/2 nucleus, <sup>23</sup>Na-NMR is also susceptible to electric field gradients caused by their nearest neighbor environment and, therefore, reflects not only the mobility of <sup>23</sup>Na<sup>+</sup> but also the molecular dynamics in the neighborhood, which are investigated in this paper. The named NMR methods were explored to study <sup>23</sup>Na<sup>+</sup> mobility in the solid electrolytes NaSICON (sodium (Na) Super Ionic CONductor, here Na<sub>3.4</sub>Zr<sub>2</sub>Si<sub>2.4</sub>P<sub>0.6</sub>O<sub>12</sub>), the salt NaTFSI (sodium bis(trifluoromethyl sulfonyl)imide), as well as in the polymer-based electrolytes PEO-NaSICON, PEO-NaTFSI, and PEO-NaTFSI-NaSICON.