Inducing High Ionic Conductivity in the Lithium Superionic Argyrodites Li6+xP1–xGexS5I for All-Solid-State Batteries

Kraft, Marvin; Ohno, Saneyuki; Zinkevich, Tatiana; Koerver, Raimund; Culver, Sean P.; Fuchs, Till; Senyshyn, Anatoliy; Indris, Sylvio; Morgan, Benjamin; Zeier, Wolfgang G.

doi:10.1021/jacs.8b10282

Cited by 370 publications

(604 citation statements)

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“…The enlarged crystal unit cell is derived from the replacement of P with Sn, which has a larger atomic radius ( R <Sn> 1.40 Å > R 1.10 Å), and the increased Li + ion concentration in the specific unit cell. The characteristic unit cell is expected to benefit the Li + ion conduction and to increase the ionic conductivity . A similar phenomenon is observed in the LPSBr‐ x Sn ( x = 0, 1, 5, 10, 12.5, 15, 20, 30) system (Figure S1, Supporting Information), but cannot occur in the LPSCl‐ x Sn ( x = 0 and 30) system (Figure S2, Supporting Information).…”

Section: Resultssupporting

confidence: 53%

“…A similar phenomenon is observed in the LPSBr‐ x Sn ( x = 0, 1, 5, 10, 12.5, 15, 20, 30) system (Figure S1, Supporting Information), but cannot occur in the LPSCl‐ x Sn ( x = 0 and 30) system (Figure S2, Supporting Information). The reason is related to the atomic radius of X in the argyrodite structure (X = Cl, Br, and I), where the larger size of the I atom endows the LPSX structure with more possibilities of various aliovalent elemental substitutions 16a…”

Section: Resultsmentioning

confidence: 99%

“…Nevertheless, the air stability of the sulfide electrolytes is predicted to be improved after Sn substitution in the PS 4 3− structure. Furthermore, the aliovalent element (Sn) substitution with larger atomic radius and lower valence compared with phosphorus (P) can expand the cell volume and increase the Li solubility in the unit cells, which can synergistically increase the corresponding ionic conductivity …”

Section: Introductionmentioning

confidence: 99%

“…However, the high I concentration in the electrolyte itself is highly anticipated to stabilize the Li metal/LPSI‐based electrolyte interface in ASSLMBs if decent ionic conductivity can be obtained. Recent studies show that the ionic conductivity of LPSI SSE can be significantly improved by aliovalent element substitutions 16a,20. Different from previous work that is fundamentally dedicated to improve the ionic conductivity fundamentally, we aim in using a versatile strategy to achieve an excellent sulfide SSE with good Li metal compatibility, improved air stability, and decent ionic conductivity, simultaneously.…”

Section: Introductionmentioning

confidence: 99%

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A Versatile Sn‐Substituted Argyrodite Sulfide Electrolyte for All‐Solid‐State Li Metal Batteries

Zhao

Liang

et al. 2020

Advanced Energy Materials

203

186

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Sulfide‐based solid‐state electrolytes (SSEs) for all‐solid‐state Li metal batteries (ASSLMBs) are attracting significant attention due to their high ionic conductivity, inherently soft properties, and decent mechanical strength. However, the poor incompatibility with Li metal and air sensitivity have hindered their application. Herein, the Sn (IV) substitution for P (V) in argyrodite sulfide Li6PS5I (LPSI) SSEs is reported, in the preparation of novel LPSI‐xSn SSEs (where x is the Sn substitution percentage). Appropriate aliovalent element substitutions with larger atomic radius (R > R

) provides the optimized LPSI‐20Sn electrolyte with a 125 times higher ionic conductivity compared to that of the LPSI electrolyte. The high ionic conductivity of LPSI‐20Sn enables the rich I‐containing electrolyte to serve as a stabilized interlayer against Li metal in sulfide‐based ASSLMBs with outstanding cycling stability and rate capability. Most importantly, benefiting from the strong Sn–S bonding in Sn‐substituted electrolytes, the LPSI‐20Sn electrolyte shows excellent structural stability and improved air stability after exposure to O2 and moisture. The versatile Sn substitution in argyrodite LPSI electrolytes is believed to provide a new and effective strategy to achieve Li metal‐compatible and air‐stable sulfide‐based SSEs for large‐scale applications.

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Section: Resultssupporting

confidence: 53%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Versatile Sn‐Substituted Argyrodite Sulfide Electrolyte for All‐Solid‐State Li Metal Batteries

Zhao

Liang

et al. 2020

Advanced Energy Materials

203

186

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“…Meanwhile, polymer-, oxide-, and sulfide-based ionic conductors are being heavily investigated as the solid electrolyte (SE) separator. [19,20] Unfortunately, thiophosphates also have a rather narrow electrochemical stability window, i.e., the onset of oxidative decomposition begins even before 3 V versus Li + /Li due to S(0)/S(−2) redox reactions, while reductive decomposition is theoretically expected at potentials of about 1.7 V versus Li + /Li due to P(+5)/P(−3) redox reactions. [2,3,18] Currently, only thiophosphates allow for the preparation of thick cathode composites with sufficient rate capability.…”

mentioning

confidence: 99%

On the Functionality of Coatings for Cathode Active Materials in Thiophosphate‐Based All‐Solid‐State Batteries

Culver

Koerver

Zeier

et al. 2019

Advanced Energy Materials

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309

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achievable by SSBs. Meanwhile, polymer-, oxide-, and sulfide-based ionic conductors are being heavily investigated as the solid electrolyte (SE) separator. [9][10][11][12][13][14][15] Nevertheless, recent estimates [16,17] show that only batteries possessing sulfide-based SEs will be leading contenders for room-temperature applications.The sulfides, which are better denoted as thiophosphates, provide the highest lithium-ion conductivity, a relatively low E modulus, and can be processed at low temperatures. [2,3,18] Currently, only thiophosphates allow for the preparation of thick cathode composites with sufficient rate capability. [19,20] Unfortunately, thiophosphates also have a rather narrow electrochemical stability window, i.e., the onset of oxidative decomposition begins even before 3 V versus Li + /Li due to S(0)/S(−2) redox reactions, while reductive decomposition is theoretically expected at potentials of about 1.7 V versus Li + /Li due to P(+5)/P(−3) redox reactions. [21,22] Importantly, the perfect SE does not actually exist. The perfect SE would combine the ionic transport properties of thiophosphates, the mechanical properties of polymers, and the oxidation stability of oxides. Therefore, in order to exploit the superionic transport properties of thiophosphates, the implementation of protective coatings to overcome the intrinsic electrochemical instabilities is most certainly a necessity. The thermodynamic prerequisites for coatings (Figure 1) have already been treated in a number of theoretical papers, [18,21,[23][24][25] which provide the initial design guidelines.Beyond the thermodynamic considerations, it is well known that within SSBs, thiophosphate SEs are oxidized and decomposed in direct contact with cathode active materials (CAMs), in particular at high potentials during charging. [2,[26][27][28] Several years ago, Takada summarized the early work on SSBs and described the need for coatings against the formation of space charge layers at the interface between high-voltage cathodes and thiophosphate SEs. [29] Haruyama et al. concluded from density functional theory calculations that space charge layers between LiCoO 2 (LCO) and thiophosphate-based SEs are responsible for high impedances and that the addition of a buffer layer reduces such effects. [30] However, experimental evidence for such claims has not yet been reported. While these considerations are certainly valuable, from a current perspective, effects arising from the space charge layer are likely overstated and the role of oxidative degradation of the SE is understated. [31] Though the The last decade has seen considerable advancements in the development of solid electrolytes for solid-state battery applications, with particular attention being paid to sulfide superionic conductors. Importantly, the intrinsic electrochemical instability of these high-performance separators highlights the notion that further progress in the field of solid-state batteries is contingent on the optimization of component material interfaces in order to se...

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Critical Current Density in Solid‐State Lithium Metal Batteries: Mechanism, Influences, and Strategies

Zhao

Yuan

et al. 2021

Adv Funct Materials

270

246

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Solid‐state lithium (Li) metal batteries (SSLMBs) have become a research hotspot in the energy storage field due to the much‐enhanced safety and high energy density. However, the SSLMBs suffer from failures including dendrite‐induced short circuits and contact‐loss‐induced high impedance, which are highly related to the Li plating/stripping kinetics and hinder the practical application of SSLMBs. The maximum endurable current density of lithium battery cycling without cell failure in SSLMB is generally defined as critical current density (CCD). Therefore, CCD is an important parameter for the application of SSLMBs, which can help to determine the rate‐determining steps of Li kinetics in solid‐state batteries. Herein, the theoretical and practical meanings for CCD from the fundamental thermodynamic and kinetic principles, failure mechanisms, CCD identifications, and influence factors for improving CCD performances are systematically reviewed. Based on these fundamental understandings, a series of strategies and outlooks for future researches on SSLMB are presented, endeavoring on increasing CCD for practical SSLMBs.

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Inducing High Ionic Conductivity in the Lithium Superionic Argyrodites Li_6+xP_1–xGe_xS₅I for All-Solid-State Batteries

Cited by 370 publications

References 50 publications

A Versatile Sn‐Substituted Argyrodite Sulfide Electrolyte for All‐Solid‐State Li Metal Batteries

A Versatile Sn‐Substituted Argyrodite Sulfide Electrolyte for All‐Solid‐State Li Metal Batteries

On the Functionality of Coatings for Cathode Active Materials in Thiophosphate‐Based All‐Solid‐State Batteries

Critical Current Density in Solid‐State Lithium Metal Batteries: Mechanism, Influences, and Strategies

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