Shaping the Future of Solid‐State Electrolytes through Computational Modeling

Baktash, Ardeshir; Reid, James C.; Yuan, Qinghong; Roman, Tanglaw; Searles, Debra J.

doi:10.1002/adma.201908041

Cited by 28 publications

(21 citation statements)

References 57 publications

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“…In order to avoid difficulties in development of force fields for these systems where charge transfer and polarizability are likely to play a role, ab initio molecule dynamics simulations are attractive and have been widely employed. However, because of the relatively low conductivity of solidstate electrolyte materials (usually lower than 10 −3 S cm −1 ), in most cases it is very computationally expensive, and sometimes impossible, to directly calculate an accurate value for conductivity of the materials at room temperature using ab initio molecular dynamics simulations 14,15 . One way to solve this problem is to calculate the diffusion coefficient at high temperatures and use the Arrhenius relation to predict a value for ionic diffusion at room temperature 14,16 .…”

Section: Introductionmentioning

confidence: 99%

“…Li 6 PS 5 Cl is an argyrodite electrolyte for which there has been much experimental and computational research. However, due to various difficulties mentioned above, the diffusion mechanism in this material is not fully understood and the predictions of the conductivity using computational and experimental results vary over orders of magnitude 15,16,23,[26][27][28][29] .…”

Section: Introductionmentioning

confidence: 99%

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Diffusion of lithium ions in Lithium-argyrodite solid-state electrolytes

et al. 2020

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The use of solid-state electrolytes to provide safer, next-generation rechargeable batteries is becoming more feasible as materials with greater stability and higher ionic diffusion coefficients are designed. However, accurate determination of diffusion coefficients in solids is problematic and reliable calculations are highly sought-after to understand how their structure can be modified to improve their performance. In this paper we compare diffusion coefficients calculated using nonequilibrium and equilibrium ab initio molecular dynamics simulations for highly diffusive solid-state electrolytes, to demonstrate the accuracy that can be obtained. Moreover, we show that ab initio nonequilibrium molecular dynamics can be used to determine diffusion coefficients when the diffusion is too slow for it to be feasible to obtain them using ab initio equilibrium simulations. Thereby, using ab initio nonequilibrium molecular dynamics simulations we are able to obtain accurate estimates of the diffusion coefficients of Li ions in Li6PS5Cl and Li5PS4Cl2, two promising electrolytes for all-solid-state batteries. Furthermore, these calculations show that the diffusion coefficient of lithium ions in Li5PS4Cl2 is higher than many other potential all-solid-state electrolytes, making it promising for future technologies. The reasons for variation in conductivities determined using computational and experimental methods are discussed. It is demonstrated that small degrees of disorder and vacancies can result in orders of magnitude differences in diffusivities of Li ions in Li6PS5Cl, and these factors are likely to contribute to inconsistencies observed in experimentally reported values. Notably, the introduction of Li-vacancies and disorder can enhance the ionic conductivity of Li6PS5Cl.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Diffusion of lithium ions in Lithium-argyrodite solid-state electrolytes

et al. 2020

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“…209 As volumetric strain of the cathode active materials during the cycling process usually results in the problem of "contact loss" at the cathode/solid-state electrolyte interface, the investigation of fracture behaviors, especially the electro-chemo-mechanics of electrodes, using FEM simulation is also noteworthy. [210][211][212][213][214] Moreover, some emerging simulation methods in the renewable energy field, such as machine learning, [215][216][217][218] the phase-field model, 219 and the CALPHAD approach, 220 are promising for the prediction and description of the cathode/solidstate electrolyte interfacial behavior in the future. LSV and CV [202] Abbreviations: CV, cyclic voltammetry; LSV, linear sweep voltammetry; RT, room temperature.…”

Section: Modeling and Advanced Characterizationmentioning

confidence: 99%

Progress and perspective of the cathode/electrolyte interface construction in all‐solid‐state lithium batteries

Zhao

et al. 2021

Carbon Energy

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Security risks of flammability and explosion represent major problems with the use of conventional lithium rechargeable batteries using a liquid electrolyte. The application of solid-state electrolytes could effectively help to avoid these safety concerns. However, integrating the solid-state electrolytes into the all-solid-state lithium batteries is still a huge challenge mainly due to the high interfacial resistance present in the entire battery, especially at the interface between the cathode and the solid-state electrolyte pellet and the interfaces inside the cathode. Herein, recent progress made from investigations of cathode/solid-state electrolyte interfacial behaviors including the contact problem, the interlayer diffusion issue, the space-charge layer effect, and electrochemical compatibility is presented according to the classification of oxide-, sulfide-, and polymer-based solid-state electrolytes. We also propose strategies for the construction of ideal next-generation cathode/solid-state electrolyte interfaces with high room-temperature ionic conductivity, stable interfacial contact during long cycling, free formation of the spacecharge region, and good compatibility with high-voltage cathodes.

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“…Although this approach has led to significant advances, it cannot provide a priori quantitative predictions of the properties of novel electrolytes. 9 − 14 A quantitative model for understanding the impacts of molecular substituents on bulk lithium electrolyte properties will significantly advance the development of next-generation energy storage devices that require molecularly optimized electrolytes with high ionic conductivities 15 at room temperature, e.g., on par with current liquid carbonate electrolytes (∼10 mS cm –1 at 298 K) or solid-state ceramics (e.g., a sulfide-based superionic conductor with ionic conductivity of 25 mS cm –1 at 298 K), 16 yet with improved safety and processability profiles. 17 Moreover, the approach to developing such a quantitative model could be broadly applied to other complex materials systems where molecular features drive macroscopic function.…”

Section: Introductionmentioning

confidence: 99%

“…In materials-based systems, however, quantitatively predicting how molecular modifications will translate across length scales to yield macroscopic property changes is especially challenging. , For example, in the field of organic lithium conducting electrolytes, where ion transport is controlled by a dynamic ensemble of all microscopic structures formed between the electrolyte solvent, a dissolved lithium salt, and other possible additives, novel electrolyte components are often designed using chemical intuition and Edisonian (i.e., trial and error) optimization. Although this approach has led to significant advances, it cannot provide a priori quantitative predictions of the properties of novel electrolytes. − A quantitative model for understanding the impacts of molecular substituents on bulk lithium electrolyte properties will significantly advance the development of next-generation energy storage devices that require molecularly optimized electrolytes with high ionic conductivities at room temperature, e.g., on par with current liquid carbonate electrolytes (∼10 mS cm –1 at 298 K) or solid-state ceramics (e.g., a sulfide-based superionic conductor with ionic conductivity of 25 mS cm –1 at 298 K), yet with improved safety and processability profiles . Moreover, the approach to developing such a quantitative model could be broadly applied to other complex materials systems where molecular features drive macroscopic function.…”

Section: Introductionmentioning

confidence: 99%

Quantitative Mapping of Molecular Substituents to Macroscopic Properties Enables Predictive Design of Oligoethylene Glycol-Based Lithium Electrolytes

et al. 2020

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Molecular details often dictate the macroscopic properties of materials, yet due to their vastly different length scales, relationships between molecular structure and bulk properties can be difficult to predict a priori , requiring Edisonian optimizations and preventing rational design. Here, we introduce an easy-to-execute strategy based on linear free energy relationships (LFERs) that enables quantitative correlation and prediction of how molecular modifications, i.e., substituents, impact the ensemble properties of materials. First, we developed substituent parameters based on inexpensive, DFT-computed energetics of elementary pairwise interactions between a given substituent and other constant components of the material. These substituent parameters were then used as inputs to regression analyses of experimentally measured bulk properties, generating a predictive statistical model. We applied this approach to a widely studied class of electrolyte materials: oligo-ethylene glycol (OEG)–LiTFSI mixtures; the resulting model enables elucidation of fundamental physical principles that govern the properties of these electrolytes and also enables prediction of the properties of novel, improved OEG–LiTFSI-based electrolytes. The framework presented here for using context-specific substituent parameters will potentially enhance the throughput of screening new molecular designs for next-generation energy storage devices and other materials-oriented contexts where classical substituent parameters (e.g., Hammett parameters) may not be available or effective.

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Shaping the Future of Solid‐State Electrolytes through Computational Modeling

Cited by 28 publications

References 57 publications

Diffusion of lithium ions in Lithium-argyrodite solid-state electrolytes

Diffusion of lithium ions in Lithium-argyrodite solid-state electrolytes

Progress and perspective of the cathode/electrolyte interface construction in all‐solid‐state lithium batteries

Quantitative Mapping of Molecular Substituents to Macroscopic Properties Enables Predictive Design of Oligoethylene Glycol-Based Lithium Electrolytes

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