Present Zn-air batteries (ZABs) are based on concentrated alkaline liquid electrolytes, with high ionic conductivity, but suffer from leakage, evaporation, and carbonate precipitation due to the semi-open characteristic of these systems. To overcome these issues, gel polymer electrolytes (GPEs), based on naturally occurring biopolymers, arise as a green option to overcome the above-mentioned limitations. In this work, a novel GPE based on pure agarose from seaweed is presented as a smart alternative to liquid (adsorbed on a separator) and gel electrolytes (based on synthetic polymers). The innovative synthesis method described can directly encapsulate concentrated KOH liquid electrolytes into an agarose matrix in one-pot; the process requiring approx. 10 min. The unique gel developed in this work, with 2 wt% agarose and 8 M KOH electrolyte, presents the best compromise between physicochemical and electrochemical properties, at lab scale. The characterization results revealed an outstanding ionic conductivity of 0.45 ± 0.05 S cm−1, ≈100% water retention up to 200–250 h, retarded Zn self-corrosion up to 30 days (symmetric cell under open circuit), average Zn utilization > 70–80% in primary ZABs in the range 1–20 mA cm−2 with peaks of ≈96%. In secondary ZABs the gel electrolyte presents high round-trip efficiency and improved cyclability at high areal capacities, under soft and severe cycling conditions, never tested before. This agarose gel represents a potential benchmark for future development of GPE-based ZABs for stationary applications.
Agarose-based Gel Electrolytes for Sustainable Primary and Secondary Zinc-Air Batteries / García-Gaitán, Estibaliz; Carmen Morant-Miñana, María; Frattini, Domenico; Maddalena, Lorenza; Fina, Alberto; Gerbaldi, Claudio; Cantero, Igor; Ortiz-Vitoriano, Nagore. - In: CHEMICAL ENGINEERING JOURNAL. - ISSN 1385-8947. - STAMPA. - 472:(2023), pp. 1-17. [10.1016/j.cej.2023.144870]
Agarose-based Gel Electrolytes for Sustainable Primary and Secondary Zinc-Air Batteries
Lorenza Maddalena;Alberto Fina;Claudio Gerbaldi;
2023
Abstract
Present Zn-air batteries (ZABs) are based on concentrated alkaline liquid electrolytes, with high ionic conductivity, but suffer from leakage, evaporation, and carbonate precipitation due to the semi-open characteristic of these systems. To overcome these issues, gel polymer electrolytes (GPEs), based on naturally occurring biopolymers, arise as a green option to overcome the above-mentioned limitations. In this work, a novel GPE based on pure agarose from seaweed is presented as a smart alternative to liquid (adsorbed on a separator) and gel electrolytes (based on synthetic polymers). The innovative synthesis method described can directly encapsulate concentrated KOH liquid electrolytes into an agarose matrix in one-pot; the process requiring approx. 10 min. The unique gel developed in this work, with 2 wt% agarose and 8 M KOH electrolyte, presents the best compromise between physicochemical and electrochemical properties, at lab scale. The characterization results revealed an outstanding ionic conductivity of 0.45 ± 0.05 S cm−1, ≈100% water retention up to 200–250 h, retarded Zn self-corrosion up to 30 days (symmetric cell under open circuit), average Zn utilization > 70–80% in primary ZABs in the range 1–20 mA cm−2 with peaks of ≈96%. In secondary ZABs the gel electrolyte presents high round-trip efficiency and improved cyclability at high areal capacities, under soft and severe cycling conditions, never tested before. This agarose gel represents a potential benchmark for future development of GPE-based ZABs for stationary applications.File | Dimensione | Formato | |
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https://hdl.handle.net/11583/2981932