Interface Limited Lithium Transport in Solid-State Batteries

Santhanagopalan, Dhamodaran; Qian, Danna; McGilvray, Thomas; Wang, Ziying; Wang, Feng; Camino, Fernando; Graetz, Jason; Dudney, Nancy J.; Meng, Ying Shirley

doi:10.1021/jz402467x

Cited by 167 publications

(191 citation statements)

References 26 publications

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“…135 Coulombic efficiency is also negatively influenced by physical stranding of inaccessible metal caused by non-uniform plating and a low density microstructure, aptly described in the literature as 'dead Li'. 140,141 A distribution of current density will manifest as a distribution of C-rates, which may create a spectrum in depth of discharge within the cathode. In the absence of other dominant failure modes, this would result in capacity fade over long duty cycles.…”

Section: Solid Electrolyte Interfacesmentioning

confidence: 99%

Review—Practical Challenges Hindering the Development of Solid State Li Ion Batteries

Kerman

Luntz

Viswanathan

et al. 2017

J. Electrochem. Soc.

584

471

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Solid state electrolyte systems boasting Li + conductivity of >10 mS cm −1 at room temperature have opened the potential for developing a solid state battery with power and energy densities that are competitive with conventional liquid electrolyte systems. The primary focus of this review is twofold. First, differences in Li penetration resistance in solid state systems are discussed, and kinetic limitations of the solid state interface are highlighted. Second, technological challenges associated with processing such systems in relevant form factors are elucidated, and architectures needed for cell level devices in the context of product development are reviewed. Specific research vectors that provide high value to advancing solid state batteries are outlined and discussed. Solid state battery systems are of great interest because of potential benefits in gravimetric and volumetric energy density, operable temperature range, and safety in comparison to traditional liquid electrolyte based systems. However, unresolved fundamental issues remain in the quest to fully understand the behavior of all-solid batteries, especially in the area of electrochemical interfaces.1 There are also a number of significant engineering challenges that require methodical effort to enable a tangible product. Some transitions from academic laboratories to entrepreneurial efforts attempting to overcome these challenges remain unsuccessful in efforts to bring a product to the market.2,3 Vital parameters that require robust understanding from a product development standpoint are material cost, cell lifetime and shelf life, cell energy density on a volumetric and gravimetric basis, operable capabilities for given temperature conditions, and safety. The advantage of energy density remains to be realized in solid state electrolytes (SSEs) since most studies to date utilize thick SSEs or cathodes with low active loading compared to liquid counterparts. 4,5 Furthermore, the desire to use SSEs in conjunction with Li metal anodes requires understanding and managing the morphology of Li metal plating, which can impact volumetric energy density. Operation at both higher and lower temperature compared to conventional technologies is a significant potential advantage of SSE systems. However, reports of solid state cells achieving parity with traditional systems at room temperature or any other temperature do not currently exist. The safety, specifically decreased flammability, of SSE systems is another potential advantage but requires ongoing validation and study.6 Unlike current liquid electrolyte systems, 7 the manufacturability and material component costs of SSEs have not been well characterized, and thus the value of these features will need to be weighed accordingly with any added cost. Operating lifetime of SSEs capturing intrinsic materials parameters such as voltage stability, 8 as well as catastrophic failure modes such as shorting, 9 have been briefly investigated, but in the absence of high energy density electrode formulations and appli...

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Section: Solid Electrolyte Interfacesmentioning

confidence: 99%

Review—Practical Challenges Hindering the Development of Solid State Li Ion Batteries

Kerman

Luntz

Viswanathan

et al. 2017

J. Electrochem. Soc.

584

471

View full text Add to dashboard Cite

show abstract

“…In rechargeable lithium ion batteries (LIB), the kinetics of interfaces and interphases between the electrodes and the electrolyte are essential for the proper battery function [1]. The instability of organic electrolytes in contact with the anode material and the resulting formation of the solid electrolyte interphase (SEI) in cells using liquid electrolytes are limiting factors for the cycle life on the one hand, and reactions at the cathode surface may cause additional problems.…”

Section: Introductionmentioning

confidence: 99%

Interphase formation on lithium solid electrolytes—An in situ approach to study interfacial reactions by photoelectron spectroscopy

et al. 2015

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“…Hence interfaces and reaction layers at the interface play a crucial role for the performance of the battery [10]. Any continuous side reaction occurring at one of the interfaces will lower the lifetime of the battery [11] due to loss of active lithium and barrier layer formation.…”

Section: Introductionmentioning

confidence: 99%

“…Nevertheless there is still a lack of knowledge about the exact nature of reaction layers and formation mechanisms between the solid electrode and the solid electrolyte. Research on the interface between the electrode and the electrolyte has been performed using analytical methods such as transmission electron microscopy [1,10], by theoretical calculations [12] or by impedance spectroscopy [13]. To our knowledge no studies on interface properties have been performed using XPS.…”

Section: Introductionmentioning

confidence: 99%

Interface reactions between LiPON and lithium studied by in-situ X-ray photoemission

2015

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Interface Limited Lithium Transport in Solid-State Batteries

Cited by 167 publications

References 26 publications

Review—Practical Challenges Hindering the Development of Solid State Li Ion Batteries

Review—Practical Challenges Hindering the Development of Solid State Li Ion Batteries

Interphase formation on lithium solid electrolytes—An in situ approach to study interfacial reactions by photoelectron spectroscopy

Interface reactions between LiPON and lithium studied by in-situ X-ray photoemission

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