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The pressing demand for long-lasting, high-power portable electronics and the emerging large-scale diffusion of electric vehicles (EVs) and energy storage from renewable sources require batteries with lower cost and improved energy density, along with enhanced cycle life and safety. State of the art Li-ion batteries (LIBs) currently on the market contain liquid electrolytes, which makes it difficult to design flexible cells, being also hazardous in terms of leakage and flammability. Within this context, a variety of solid-state electrolytes (viz., polymeric, inorganic, composites thereof) have been investigated to date as, in principle, they enable extension of the operating temperature range of a device, also ensuring higher safety even in the case of fire, together with enhanced energy and power densities, thus favoring the transition to all-solid-state batteries. In the field of polymer electrolytes, the development of innovative single-ion conductors has attracted increasing interest in recent years, mainly because of their intrinsic safety and peculiar chemical structure that can be tailored as desired to display unique properties, such as tLi+ ≈ 1. Nevertheless, their practical application is still limited by low ionic conductivity (σ, far below 10–5 S cm–1 at 25 °C). Starting from the previous experience in the development of single-ion conducting copolymers based on the specifically designed lithium 1-[3-(methacryloyloxy)propylsulfonyl]-1-(trifluoromethylsulfonyl)imide anionic monomer, this work is focused on the challenging synthesis of macro-RAFT agent based on polycarbonate backbone chain, which is then used in controlling the polymerization of ionic blocks. Moreover, the combination of polycarbonate, aimed to improve the electrochemical stability window ( 5 V vs. Li+/Li), and polyethylene glycol (PEG) based blocks is explored, merging their properties to achieve enhanced performance. Other crosslinked polymeric systems are also under the first stage of development in our labs to assure improved ionic conductivity. The result is the fabrication of solid-state polymer electrolytes that meet the request of high ionic mobility for ambient temperature practical application, with the chance to exploit their safe use with high voltage cathodes, thus enhancing the overall device energy density.

Innovative single-ion conducting solid electrolytes for safe, high performing energy storage devices / Lingua, G.; Falco, M.; Bella, F.; Meligrana, G.; Shaplov, A. S.; Gerbaldi, C.. - ELETTRONICO. - (2020), pp. 36-36. (Intervento presentato al convegno Le Studium Conference – Towards Futuristic Energy Storage; paving its way through Supercapacitors, Li-ion batteries and beyond tenutosi a Tours (France) nel 22-24 January 2020).

Innovative single-ion conducting solid electrolytes for safe, high performing energy storage devices

G. Lingua;M. Falco;F. Bella;G. Meligrana;C. Gerbaldi
2020

Abstract

The pressing demand for long-lasting, high-power portable electronics and the emerging large-scale diffusion of electric vehicles (EVs) and energy storage from renewable sources require batteries with lower cost and improved energy density, along with enhanced cycle life and safety. State of the art Li-ion batteries (LIBs) currently on the market contain liquid electrolytes, which makes it difficult to design flexible cells, being also hazardous in terms of leakage and flammability. Within this context, a variety of solid-state electrolytes (viz., polymeric, inorganic, composites thereof) have been investigated to date as, in principle, they enable extension of the operating temperature range of a device, also ensuring higher safety even in the case of fire, together with enhanced energy and power densities, thus favoring the transition to all-solid-state batteries. In the field of polymer electrolytes, the development of innovative single-ion conductors has attracted increasing interest in recent years, mainly because of their intrinsic safety and peculiar chemical structure that can be tailored as desired to display unique properties, such as tLi+ ≈ 1. Nevertheless, their practical application is still limited by low ionic conductivity (σ, far below 10–5 S cm–1 at 25 °C). Starting from the previous experience in the development of single-ion conducting copolymers based on the specifically designed lithium 1-[3-(methacryloyloxy)propylsulfonyl]-1-(trifluoromethylsulfonyl)imide anionic monomer, this work is focused on the challenging synthesis of macro-RAFT agent based on polycarbonate backbone chain, which is then used in controlling the polymerization of ionic blocks. Moreover, the combination of polycarbonate, aimed to improve the electrochemical stability window ( 5 V vs. Li+/Li), and polyethylene glycol (PEG) based blocks is explored, merging their properties to achieve enhanced performance. Other crosslinked polymeric systems are also under the first stage of development in our labs to assure improved ionic conductivity. The result is the fabrication of solid-state polymer electrolytes that meet the request of high ionic mobility for ambient temperature practical application, with the chance to exploit their safe use with high voltage cathodes, thus enhancing the overall device energy density.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2808998