Revisiting Amides as Cosolvents for Flame Resistant Sodium Bis(oxalato)borate in Triethyl Phosphate Electrolyte

Aram Hall, Charles; Colbin, Lars O. Simon; Buckel, Alexander; Younesi, Reza

doi:10.1002/batt.202300338

Batteries & Supercaps

2023

DOI: 10.1002/batt.202300338

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Revisiting Amides as Cosolvents for Flame Resistant Sodium Bis(oxalato)borate in Triethyl Phosphate Electrolyte

Charles Aram Hall,

Lars O. Simon Colbin,

Alexander Buckel

et al.

Abstract: In selecting electrolytes for Na‐ion batteries, simply importing the analogue of common Li‐ion battery electrolytes to Na‐ion batteries does not address safety concerns like toxicity and flammability. Electrolytes based on sodium bis(oxalato)borate (NaBOB) in organophosphates like triethyl phosphate (TEP) largely alleviate these specific safety concerns. However, it may be beneficial to obtain solutions with higher ionic conductivities than NaBOB in TEP, and compare the performance in Na‐ion batteries with hig… Show more

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2024

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Cited by 3 publications

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Designing Nonflammable Liquid Electrolytes for Safe Li‐Ion Batteries

Xie,

2024

Advanced Materials

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Li‐ion batteries are essential technologies for electronic products in our daily life. However, serious fire safety concerns that are closely associated with the flammable liquid electrolyte remains a key challenge. Tremendous effort has been devoted to designing non‐flammable liquid electrolytes. It's critical to gain comprehensive insights into non‐flammability design and inspire more efficient approaches for building safer Li‐ion batteries. This review presents current mechanistic understanding of safety issues and discusses state‐of‐the‐art non‐flammable liquid electrolytes design for Li‐ion batteries based on molecule, solvation, and battery compatibility level. Various safety test methods are discussed for reliable safety risk evaluation. Finally, the challenges and perspectives of the non‐flammability design for Li‐ion electrolyte are summarized.This article is protected by copyright. All rights reserved

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Designing Nonflammable Liquid Electrolytes for Safe Li‐Ion Batteries

Xie,

2024

Advanced Materials

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Investigation of Electrolyte Salts in Non‐Flammable Triethyl Phosphate for Sodium‐Ion Batteries

Van Ekeren,

Dettmann,

Tesfamhret

et al. 2024

Batteries & Supercaps

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Five different electrolyte salts, namely NaBF4, NaClO4, NaDFOB, NaFSI and NaPF6, were evaluated in non‐flammable triethyl phosphate (TEP) based electrolyte solutions in sodium‐ion full‐cells using high‐mass loading Prussian white and hard carbon electrodes. Their impact on the viscosity, ionic conductivity and solvation structure was analyzed, revealing that NaFSI‐based electrolytes exhibited a stronger interaction with TEP and less ion‐pairing than the other salts, resulting in the highest ionic conductivity at a concentration of 0.8 m (mol/kg). Galvanostatic cycling experiments showed that none of the electrolyte salts dissolved in TEP forms an efficient passivation layer. However, adding 1 wt.% vinylene carbonate (VC) significantly improved cycling performance for the cells with NaBF4, NaDFOB or NaFSI, but not with NaClO4 or NaPF6. Additionally, NaFSI in TEP with 1 wt.% VC electrolyte solution showed minimal gas evolution during the formation cycling (< 8 mbar). In a 1 Ah multilayer pouch cell, 0.8 m NaFSI in TEP with 1 wt.% VC showed promising results with 88% capacity retention after 200 cycles. X‐ray photoelectron spectroscopy analysis revealed that the addition of VC results in the formation of a thin SEI and minimized TEP decomposition on hard carbon, especially for 0.8 m NaFSI TEP with 1 wt.% VC.

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PFAS-Free Energy Storage: Investigating Alternatives for Lithium-Ion Batteries

Savvidou,

Rensmo,

Benskin

et al. 2024

Environ. Sci. Technol.

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The class-wide restriction proposal on perfluoroalkyl and polyfluoroalkyl substances (PFAS) in the European Union is expected to affect a wide range of commercial sectors, including the lithium-ion battery (LIB) industry, where both polymeric and low molecular weight PFAS are used. The PFAS restriction dossiers currently state that there is weak evidence for viable alternatives to the use of PFAS in LIBs. In this Perspective, we summarize both the peer-reviewed literature and expert opinions from academia and industry to verify the legitimacy of the claims surrounding the lack of alternatives. Our assessment is limited to the electrodes and electrolyte, which account for the most critical uses of PFAS in LIB cells. Companies that already offer or are developing PFAS-free electrode and electrolyte materials were identified. There are also indications that PFAS-free electrolytes are in development by at least one other company, but there is no information regarding the alternative chemistries being proposed. Our review suggests that it is technically feasible to make PFAS-free batteries for battery applications, but PFAS-free solutions are not currently well-established on the market. Successful substitution of PFAS will require an appropriate balance among battery performance, the environmental effects associated with hazardous materials and chemicals, and economic considerations.

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Revisiting Amides as Cosolvents for Flame Resistant Sodium Bis(oxalato)borate in Triethyl Phosphate Electrolyte

Cited by 3 publications

References 30 publications

Designing Nonflammable Liquid Electrolytes for Safe Li‐Ion Batteries

Designing Nonflammable Liquid Electrolytes for Safe Li‐Ion Batteries

Investigation of Electrolyte Salts in Non‐Flammable Triethyl Phosphate for Sodium‐Ion Batteries

PFAS-Free Energy Storage: Investigating Alternatives for Lithium-Ion Batteries

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