Interfaces Between Cathode and Electrolyte in Solid State Lithium Batteries: Challenges and Perspectives

Nie, Kaihui; Hong, Yanshuai; Qiu, Jiliang; Li, Qinghao; Yu, Xiqian; Li, Hong; Chen, Liquan

doi:10.3389/fchem.2018.00616

Cited by 188 publications

(144 citation statements)

References 116 publications

(168 reference statements)

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“…The high‐voltage compatibility represents the capability of electrolyte to restrain oxidative decomposition. Thermodynamically, as shown in Figure , a high‐voltage‐stable SPE means all the components of polymer electrolyte (polymer, lithium salts, and additives) must simultaneously have lower energy level of highest occupied molecular orbital (HOMO) than cathode potential ( µ c ) . However, due to the strong and complicated oxidation state of the cathode materials during lithium deintercalation process, µ c could shift down to the lower state than the HOMO of SPEs, resulting an interfacial parasitic reaction.…”

Section: Introductionmentioning

confidence: 99%

Intermolecular Chemistry in Solid Polymer Electrolytes for High‐Energy‐Density Lithium Batteries

et al. 2019

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Solid polymer electrolytes (SPEs) have aroused wide interest in lithium batteries because of their sufficient mechanical properties, superior safety performances, and excellent processability. However, ionic conductivity and high‐voltage compatibility of SPEs are still yet to meet the requirement of future energy‐storage systems, representing significant barriers to progress. In this regard, intermolecular interactions in SPEs have attracted attention, and they can significantly impact on the Li+ motion and frontier orbital energy level of SPEs. Recent advances in improving electrochemcial performance of SPEs are reviewed, and the underlying mechanism of these proposed strategies related to intermolecular interaction is discussed, including ion–dipole, hydrogen bonds, π–π stacking, and Lewis acid–base interactions. It is hoped that this review can inspire a deeper consideration on this critical issue, which can pave new pathway to improve ionic conductivity and high‐voltage performance of SPEs.

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Section: Introductionmentioning

confidence: 99%

Intermolecular Chemistry in Solid Polymer Electrolytes for High‐Energy‐Density Lithium Batteries

et al. 2019

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“…For example, Famprikis et al [51] and Zhang et al [116] reported on the fundamentals of electrolytes and Oudenhoven et al [117], Julien and Mauger [60], and Rambabu et al [118] reviewed the technology of solid-state microbatteries. Moreover, in situ and ex situ techniques were explored for elucidating the solid electrode/electrolyte interfaces [40,67,80,98,[119][120][121][122][123] and computational methods were reviewed by Xiao et al [94] for understanding the conduction mechanisms in both oxide and sulfide electrolytes.…”

Section: Introductionmentioning

confidence: 99%

Sulfide and Oxide Inorganic Solid Electrolytes for All-Solid-State Li Batteries: A Review

et al. 2020

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Energy storage materials are finding increasing applications in our daily lives, for devices such as mobile phones and electric vehicles. Current commercial batteries use flammable liquid electrolytes, which are unsafe, toxic, and environmentally unfriendly with low chemical stability. Recently, solid electrolytes have been extensively studied as alternative electrolytes to address these shortcomings. Herein, we report the early history, synthesis and characterization, mechanical properties, and Li+ ion transport mechanisms of inorganic sulfide and oxide electrolytes. Furthermore, we highlight the importance of the fabrication technology and experimental conditions, such as the effects of pressure and operating parameters, on the electrochemical performance of all-solid-state Li batteries. In particular, we emphasize promising electrolyte systems based on sulfides and argyrodites, such as LiPS5Cl and β-Li3PS4, oxide electrolytes, bare and doped Li7La3Zr2O12 garnet, NASICON-type structures, and perovskite electrolyte materials. Moreover, we discuss the present and future challenges that all-solid-state batteries face for large-scale industrial applications.

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“…Presently, the materials research community is wholly engaged in enabling the necessary radical departure(s) from conventional SIB technology. The replacement of the ubiquitous liquid electrolyte in commercial SIB with a solid-state electrolyte (SSE), the new battery configuration being termed an "all-solidstate battery" (ASSB), represents one such paradigmatic shift in energy storage technology (Nie et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Emerging Role of Non-crystalline Electrolytes in Solid-State Battery Research

et al. 2020

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As the need for new modalities of energy storage becomes increasingly important, allsolid-state secondary ion batteries seem poised to address a portion of tomorrow's energy needs. The success of such batteries is contingent on the solid-state electrolyte (SSE) meeting a set of material demands, including high bulk and interfacial ionic conductivity, processability with electrodes, electrode interfacial stability, thermal stability, etc. The demanding criteria for an ideal SSE has translated into decades of research devoted to discovering new electrolytes and modifying their structure/processing to improve their properties. While much research has focused on the electrolyte properties of polycrystalline ceramics, non-crystalline materials (glasses, amorphous solids, and partially crystallized materials) have demonstrated unique advantages in processability, stability, tunability, etc. These non-crystalline electrolytes are also fundamentally interesting for their potential contributions toward understanding ionic conduction in the solid state. In this review, we first review a decade of advances in two distinct families of non-crystalline lithium-ion electrolytes: lithium thiophosphate and lithium phosphate oxynitride. In doing so, we demonstrate two pathways for non-crystalline electrolytes to address the barriers toward development of all-solidstate batteries, viz., interfacial stability and conduction. Finally, we conclude with some discussion of the development of fundamental models of ionic conduction in the non-crystalline state, including the ongoing debate between strong and weak electrolyte theories. Collectively, these discussions make a promising case for the role of non-crystalline electrolytes in the next generation of energy storage technology.

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Interfaces Between Cathode and Electrolyte in Solid State Lithium Batteries: Challenges and Perspectives

Cited by 188 publications

References 116 publications

Intermolecular Chemistry in Solid Polymer Electrolytes for High‐Energy‐Density Lithium Batteries

Intermolecular Chemistry in Solid Polymer Electrolytes for High‐Energy‐Density Lithium Batteries

Sulfide and Oxide Inorganic Solid Electrolytes for All-Solid-State Li Batteries: A Review

Emerging Role of Non-crystalline Electrolytes in Solid-State Battery Research

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