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Solid-state electrolyte

All Solid-State Battery with the solid-state electrolyte.

A solid-state electrolyte (SSE) is a solid ionic conductor and electron-insulating material and it is the characteristic component of the solid-state battery. It is useful for applications in electrical energy storage (EES) in substitution of the liquid electrolytes found in particular in lithium-ion battery.[1][2] The main advantages are the absolute safety, no issues of leakages of toxic organic solvents, low flammability, non-volatility, mechanical and thermal stability, easy processability, low self-discharge, higher achievable power density and cyclability.[3] This makes possible, for example, the use of a lithium metal anode in a practical device, without the intrinsic limitations of a liquid electrolyte thanks to the property of lithium dendrite suppression in the presence of a solid-state electrolyte membrane. The use of a high capacity anode and low reduction potential, like lithium with a specific capacity of 3860 mAh g−1 and a reduction potential of -3.04 V vs SHE, in substitution of the traditional low capacity graphite, which exhibits a theoretical capacity of 372 mAh g−1 in its fully lithiated state of LiC6,[4] is the first step in the realization of a lighter, thinner and cheaper rechargeable battery.[5] Moreover, this allows the reach of gravimetric and volumetric energy densities, high enough to achieve 500 miles per single charge in an electric vehicle.[6] Despite the promising advantages, there are still many limitations that are hindering the transition of SSEs from academia research to large-scale production, depending mainly on the poor ionic conductivity compared to that of liquid counterparts. However, many car OEMs (Toyota, BMW, Honda, Hyundai) expect to integrate these systems into viable devices and to commercialize solid-state battery-based electric vehicles by 2025.[7][8]

  1. ^ "Japanese Government Partners With Manufacturers On Solid State Battery Research". CleanTechnica. 7 May 2018.
  2. ^ "German Federal Government Invests In Solid State Battery Research". CleanTechnica. 29 October 2018.
  3. ^ Chen, Zhen; Kim, Guk-Tae; Wang, Zeli; Bresser, Dominic; Qin, Bingsheng; Geiger, Dorin; Kaiser, Ute; Wang, Xuesen; Shen, Ze Xiang; Passerini, Stefano (October 2019). "4-V flexible all-solid-state lithium polymer batteries". Nano Energy. 64: 103986. doi:10.1016/j.nanoen.2019.103986. hdl:10356/149966. S2CID 201287650.
  4. ^ Polymer-Derived SiOC Integrated with a Graphene Aerogel As a Highly Stable Li-Ion Battery Anode Applied Materials and Interfaces 2020
  5. ^ Wang, Renheng; Cui, Weisheng; Chu, Fulu; Wu, Feixiang (September 2020). "Lithium metal anodes: Present and future". Journal of Energy Chemistry. 48: 145–159. doi:10.1016/j.jechem.2019.12.024.
  6. ^ Baldwin, Roberto (12 March 2020). "Samsung Reveals Breakthrough: Solid-State EV Battery with 500-Mile Range". Car and Driver.
  7. ^ Kim, Taehoon; Song, Wentao; Son, Dae-Yong; Ono, Luis K.; Qi, Yabing (2019). "Lithium-ion batteries: outlook on present, future, and hybridized technologies". Journal of Materials Chemistry A. 7 (7): 2942–2964. doi:10.1039/c8ta10513h. S2CID 104366580.
  8. ^ "Solid-State Batteries". FutureBridge. 6 July 2019.

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