Structural and Electrochemical Consequences of Al and Ga Cosubstitution in Li₇La₃Zr₂O₁₂ Solid Electrolytes

Abstract: Several “Beyond Li-Ion Battery” concepts such as all solid-state batteries and hybrid liquid/solid systems envision the use of a solid electrolyte to protect Li-metal anodes. These configurations are very attractive due to the possibility of exceptionally high energy densities and high (dis)charge rates, but they are far from being realized practically due to a number of issues including high interfacial resistance and difficulties associated with fabrication. One of the most promising solid electrolyte system… Show more

“…The resulting ASR of 1088 Ω cm 2 is significantly larger than those observed for the Al- and Ga-stabilized counterparts obtained by similar preparation routes. 4 A cyclic voltammogram of the Li|LLZO:Fe|Au cell was recorded to check the electrochemical voltage stability window of LLZO:Fe (see Figure 3). We observe small reduction and oxidation peaks at low potentials because of the alloying reaction of Au and Li and the extraction of Li from the alloy.…”

“…The interfacial impedance measurements were taken shortly after the Li|LLZO|Li cell was assembled. 4 During this time, the black coloration region may be dynamically evolving and resulted in a possible mixed conduction black layer. We were not able to separate partial electronic and ionic conduction.…”

Interface Instability of Fe-Stabilized Li₇La₃Zr₂O₁₂ versus Li Metal

“…The resulting ASR of 1088 Ω cm 2 is significantly larger than those observed for the Al- and Ga-stabilized counterparts obtained by similar preparation routes. 4 A cyclic voltammogram of the Li|LLZO:Fe|Au cell was recorded to check the electrochemical voltage stability window of LLZO:Fe (see Figure 3). We observe small reduction and oxidation peaks at low potentials because of the alloying reaction of Au and Li and the extraction of Li from the alloy.…”

“…The interfacial impedance measurements were taken shortly after the Li|LLZO|Li cell was assembled. 4 During this time, the black coloration region may be dynamically evolving and resulted in a possible mixed conduction black layer. We were not able to separate partial electronic and ionic conduction.…”

Interface Instability of Fe-Stabilized Li₇La₃Zr₂O₁₂ versus Li Metal

“…Regarding Li 7 La 3 Zr 2 O 12 , its tetragonal modification is a moderate Li ion conductor [119]. The replacement of La and Zr ions with isovalent or aliovalent cations greatly affects, however, (i) the defect chemistry, (ii) the crystal structure parameters and (iii) also the Li content of the garnets [40,[120][121][122]. These variations lead to a series of oxides that may largely differ in ionic conductivities [19].…”

“…The search for suitable materials that are characterized by ultra-fast ion dynamics [32]; LISICON (Li 14 Zn(GeO 4 ) 4 ) [33]; Li-β-alumina [34]; Li 10 GeP 2 S 12 [35]; s-Li 3 N (pure, sintered) [36]; d-Li 3 N (doped with H) [37]; tetragonal LLZ (Li 7 La 3 Zr 2 O 12 ) [38]; cubic-Al-LLZO (Li 7 La 3 Zr 2 O 12 with 0.9 wt% Al added) [39]; cubic-Ga-LLZO (Ga-containing garnet, bulk values) [40]; LiBSO (0.3 LiBO 2 -0.7 Li 2 SO 4 , thin film) [41]; LiPON (lithium phosphorous oxynitride, thin film) [42] [56]; LLTO (La 0. 51 Li 0.34 TiO 2.94 , bulk conductivity) [57] and negligible electronic transport has already reached an unprecedented level.…”

“…[19,22] where the relationships between chemical composition, structure and ionic conductivity of the Li-stuffed garnet-type oxide as well as relevant Li ion conduction mechanisms are discussed. Among the known Li-stuffed garnets, Li 6.4 La 3 Zr 1.4 Ta 0.6 O 12 and Al(Ga)-stabilized cubic-Li 7 La 3 Zr 2 O 12 exhibit the highest Li-ion conductivity (10 −3 S cm −1 at 295 K) [19,22,40]. While activation energies derived from impedance spectroscopy lie around 0.2 eV for the sulfides [64], for the highly conducting garnet-based oxides values of ca.…”

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