Two-Dimensional Substitution: Toward a Better Understanding of the Structure–Transport Correlations in the Li-Superionic Thio-LISICONs

Abstract: A deeper understanding of the relationships among composition–structure–transport properties in inorganic solid ionic conductors is of paramount importance to develop highly conductive phases for future employment in solid-state Li-ion battery applications. To shed light on the mechanisms that regulate these relationships, in this work, we perform a “two-dimensional” substitution series in the thio-LISICON family Li4Ge1–x Sn x S4–y Se y . The structural modifications brought up by the elemental substitutions w… Show more

“…Between −70 and 120 °C, the data of Li 4 Ge 4 Se 10 follow an Arrhenius behavior with an activation energy E A of 0.49 eV and an ionic conductivity at room temperature (RT) (σ RT ) of 1.7 × 10 –6 S/cm (Figure ). This value is close to the one reported for Li 4 GeSe 4 (2 × 10 –6 S/cm); , hence, it is 1 order of magnitude higher than that of Li 4 GeS 4 , the thio-LISICON parent compound, and lower than the values reported for Li 4 SnS 4 or Li 4 SnSe 4 (7 × 10 –5 S/cm, 2 × 10 –5 S/cm), , which equally situates the performance of Li 4 Ge 4 Se 10 between that of the chalcogenido tetrelates based on either [GeS 4 ] 4– or [SnE 4 ] 4– anions.…”

“…In contrast to the elemental combinations mentioned above, lithium selenido germanates have not been investigated to a great extent, with only two known compounds so far, Li 3 Ge 3 Se 6 and Li 4 GeSe 4 . , We thus extended our investigations of selenido germanates toward Li + salts in the absence or presence of solvents. Herein, we report our first resultswith regard to chemical treatment and crystallization under different conditions and with regard to ionic conductivity.…”

Different Chemical Environments of [Ge₄Se₁₀]^4– in the Li⁺ Compounds [Li₄(H₂O)₁₆][Ge₄Se₁₀]·4.33H₂O, [{Li₄(thf)₁₂}Ge₄Se₁₀], and [Li₂(H₂O)₈][MnGe₄Se₁₀], and Ionic Conductivity of Underlying “Li₄Ge₄Se₁₀”

“…Between −70 and 120 °C, the data of Li 4 Ge 4 Se 10 follow an Arrhenius behavior with an activation energy E A of 0.49 eV and an ionic conductivity at room temperature (RT) (σ RT ) of 1.7 × 10 –6 S/cm (Figure ). This value is close to the one reported for Li 4 GeSe 4 (2 × 10 –6 S/cm); , hence, it is 1 order of magnitude higher than that of Li 4 GeS 4 , the thio-LISICON parent compound, and lower than the values reported for Li 4 SnS 4 or Li 4 SnSe 4 (7 × 10 –5 S/cm, 2 × 10 –5 S/cm), , which equally situates the performance of Li 4 Ge 4 Se 10 between that of the chalcogenido tetrelates based on either [GeS 4 ] 4– or [SnE 4 ] 4– anions.…”

“…In contrast to the elemental combinations mentioned above, lithium selenido germanates have not been investigated to a great extent, with only two known compounds so far, Li 3 Ge 3 Se 6 and Li 4 GeSe 4 . , We thus extended our investigations of selenido germanates toward Li + salts in the absence or presence of solvents. Herein, we report our first resultswith regard to chemical treatment and crystallization under different conditions and with regard to ionic conductivity.…”

Different Chemical Environments of [Ge₄Se₁₀]^4– in the Li⁺ Compounds [Li₄(H₂O)₁₆][Ge₄Se₁₀]·4.33H₂O, [{Li₄(thf)₁₂}Ge₄Se₁₀], and [Li₂(H₂O)₈][MnGe₄Se₁₀], and Ionic Conductivity of Underlying “Li₄Ge₄Se₁₀”

“…1 The application of solid electrolytes improve the battery not only in terms of reduced risk of combustion, compared to liquid electrolytes, but also by enabling battery use at a wider temperature range and higher current densities for operation. 1,2 The search for the replacement of liquid electrolytes led to the discovery of several promising solid electrolytes including garnets, [3][4][5] Li10GeP2S12 6-8 , argyrodites [9][10][11] and thio-LISICONs [12][13][14][15] , all of which were investigated thoroughly by iso-or aliovalent substitutions to determine influences on ionic transport, for instance the width of diffusion pathway, 5,16,17 lattice polarizability 9,18,19 or Li + /vacancy density. 13,[20][21][22] Recently, the ternary halide electrolytes Li3MX6 (M = Y, Er, In, Sc and X = Cl, Br, I) have drawn attention for exhibiting conductivities in the mS•cm -1 -range at room temperature in combination with an enhanced electrochemical stability compared to the sulfide electrolytes.…”

Exploring Aliovalent Substitutions in the Lithium Halide Superionic Conductor Li_3–xIn_1–xZr_xCl₆ (0 ≤ x ≤ 0.5)

“…Diffusion may also be limited to one-dimensional channels, which can be easily blocked. The importance of having a percolating network of low-barrier transitions has [84,128,129] structural: destabilized energy minima in amorphous phase due to lack of crystalline order [95]; structural arrangement and local coordination symmetry of anions impacts diffusivity [130,131]; vacancy-induced site disorder and partial site occupancy induce mobility [91]; atomic substitution can tune lattice volume and relative cation site preference to maximize frustration [132,133]; ion conduction correlates with lack of cation site preference [134] dynamical: enhanced [PS 4 ] chemical: inductive effect through S interaction affects barriers [38][39][40]; substitution with O changes bonding [41] structural: site occupancies disorder above transition temperature [93]; Ge/P site disorder can increase conductivity [135]; O substitution for S changes site occupancy [41]; distorted intrinsic site symmetry, fluctuations in the coordination environment, and lack of clear site preference enhance frustration in Ti-based variant [58]; conduction pathway changes with local site volume [40] dynamical: enhanced [PS 4 ] 3− reorientations from structural or chemical modification lead to faster conductivity [89,93,94]; highly correlated migration in sulfide and oxygen-substituted variants [10,41] . [68] and by Morgan in the context of argyrodites [61].…”

Paradigms of frustration in superionic solid electrolytes