Your search keyword '"SEI"' showing total 5 results

1. Anion Chemistry towards On‐Site Construction of Solid‐Electrolyte Interface for Highly Stable Metallic Zn Anode.

Author

Yao, Hong, Li, Yuhang, Chen, Zibo, Chen, Jianyu, Du, Cheng‐Feng, Chen, Yingqian, Chen, Junze, Wong, Ming Wah, Zhao, Jin, and Yuan, Du

Abstract

Reversibility of metallic Zn anode serves as the corner stone for the development of aqueous Zn metal battery, which motivates scrutinizing the electrolyte‐Zn interface. As the representative organic zinc salt, zinc trifluorosulfonate (Zn(OTf)2) facilitates a broad class of aqueous electrolytes, however, the stability issue of Zn anode remains crucial. The great challenge lies in the lack of Zn anode protection by the pristinely formed surface structure in aqueous Zn(OTf)2 electrolytes. Accordingly, an electrochemical route was developed to grow a uniform zinc trifluorosulfonate hydroxide (ZTH) layer on Zn anode as an artificial SEI, via regulation on metal dissolution and strong coordination ability of zinc ions. Co‐precipitation was proposed to be the formation mechanism for the artificial SEI, where the reduction stability of OTf− anion and the low‐symmetry layer structure of ZTH was unmasked. This artificial SEI favors interfacial kinetics, depresses side reactions, and well maintains its integrity during cycling, leading to a prolonged lifespan of Zn stripping/plating with a high DOD of ~85 %, and an improved cycling stability of ~92 % retention rate for V2O5/Zn cell at 1 A g−1. The unveiled role of anion on Zn anode drives the contemplation on the surface chemistry for the blooming aqueous rechargeable battery. [ABSTRACT FROM AUTHOR]

Published

2024

2. Reactive Solid Polymer Layer: From a Single Fluoropolymer to Divergent Fluorinated Interface.

Author

Ma, Mingyu, Guo, Xing, Wen, Peng, Han, Shantao, Zhang, Lu, Liu, Yixuan, Lin, Xinrong, and Chen, Mao

Subjects

*REACTIVE polymers, *SOLID electrolytes, *LITHIUM cells, *INTERFACE stability, *ELECTROCHEMICAL experiments

Abstract

Controlling the structure and chemistry of solid electrolyte interphase (SEI) underpins the stability of electrolyte‐electrode interface, and is crucial for advancing rechargeable lithium metal batteries (LMBs). Here, we utilized photo‐controlled copolymerization to achieve the on‐demand synthesis of fluorosulfonyl fluoropolymers as unprecedented artificial SEI layers on Li metal anodes. This work not only enables instant formation of a hybrid polymer‐inorganic interphase that consists of a polymer‐enriched top layer and a LiF‐fortified bottom layer, originating from a single polymeric component, but also imparts various desirable physical properties (e.g. good mechanical strength and flexibility, high ion conductivity, low overpotential) to SEI via a single‐to‐divergent strategy. Model reactions and structural characterizations supported the formation of a divergent fluorinated interphase, which furnished prolonged stabilization of Li deposition, high coulombic efficiency and improved cycling behavior in electrochemical experiments. This work highlights the great potential of exploring reactive polymers as versatile coatings to stabilize Li metal anodes, providing a promising avenue to solve electrode‐electrolyte interfacial problems for LMBs. [ABSTRACT FROM AUTHOR]

Published

2024

3. Low Concentration Sulfolane‐Based Electrolyte for High Voltage Lithium Metal Batteries.

Author

Li, Pengcheng, Zhang, Hao, Lu, Jun, and Li, Ge

Subjects

*LITHIUM cells, *HIGH voltages, *ELECTROLYTES, *SOLID electrolytes, *LITHIUM, *IONIC conductivity

Abstract

Electrolyte engineering is crucial for the commercialization of lithium metal batteries. Here, lithium metal is stabilized in the highly reactive sulfolane‐based electrolyte under low concentration (0.25 M) for the first time. Inorganic‐polymer hybrid solid electrolyte interphase (SEI) with high ionic conductivity, low bonding with lithium and high flexibility enables dense chunky lithium deposition and high plating/stripping efficiency. Low concentration electrolyte (LCE) also enables excellent cycling stability of LiNi0.5Co0.2Mn0.3O2 (NCM523)/Li cells at 1 C (90.7 % retention after 500 cycles) and 0.3 C (83.3 % retention after 1000 cycles). With a low N/P ratio (≈2), the capacity retention for NCM523/Li cells can achieve 94.3 % after 100 cycles at 0.3 C. Exploring the LCE is of paramount significance because it provides more possibilities of the lithium salt selections, especially reviving some lithium salts that are excluded before due to their low solubility. More importantly, LCE has the significant advantage of commercialization due to its cost‐effectiveness. [ABSTRACT FROM AUTHOR]

Published

2023

4. Sodium Borates: Expanding the Electrolyte Selection for Sodium‐Ion Batteries.

Author

Ould, Darren M. C., Menkin, Svetlana, Smith, Holly E., Riesgo‐Gonzalez, Victor, Jónsson, Erlendur, O'Keefe, Christopher A., Coowar, Fazlil, Barker, Jerry, Bond, Andrew D., Grey, Clare P., and Wright, Dominic S.

Subjects

*BORAX, *ELECTROLYTES, *IMPEDANCE spectroscopy, *CYCLIC voltammetry, *SODIUM salts

Abstract

Sodium‐ion batteries (SIBs) are a promising grid‐level storage technology due to the abundance and low cost of sodium. The development of new electrolytes for SIBs is imperative since it impacts battery life and capacity. Currently, sodium hexafluorophosphate (NaPF6) is used as the benchmark salt, but is highly hygroscopic and generates toxic HF. This work describes the synthesis of a series of sodium borate salts, with electrochemical studies revealing that Na[B(hfip)4]⋅DME (hfip=hexafluoroisopropyloxy, OiPrF) and Na[B(pp)2] (pp=perfluorinated pinacolato, O2C2(CF3)4) have excellent electrochemical performance. The [B(pp)2]− anion also exhibits a high tolerance to air and water. Both electrolytes give more stable electrode‐electrolyte interfaces than conventionally used NaPF6, as demonstrated by impedance spectroscopy and cyclic voltammetry. Furthermore, they give greater cycling stability and comparable capacity to NaPF6 for SIBs, as shown in commercial pouch cells. [ABSTRACT FROM AUTHOR]

Published

2022

5. New Route to Battery Grade NaPF6 for Na‐Ion Batteries: Expanding the Accessible Concentration.

Author

Ould, Darren M. C., Menkin, Svetlana, O'Keefe, Christopher A., Coowar, Fazlil, Barker, Jerry, Grey, Clare P., and Wright, Dominic S.

Subjects

*SODIUM ions, *STORAGE batteries, *FLUOROETHYLENE, *AMMONIUM acetate, *ELECTROLYTES, *SODIUM, *SOLVENTS, *ELECTRIC batteries

Abstract

Sodium‐ion batteries represent a promising alternative to lithium‐ion systems. However, the rapid growth of sodium‐ion battery technology requires a sustainable and scalable synthetic route to high‐grade sodium hexafluorophosphate. This work demonstrates a new multi‐gram scale synthesis of NaPF6 in which the reaction of ammonium hexafluorophosphate with sodium metal in THF solvent generates the electrolyte salt with the absence of the impurities that are common in commercial material. The high purity of the electrolyte (absence of insoluble NaF) allows for concentrations up to 3 M to be obtained accurately in binary carbonate battery solvent. Electrochemical characterization shows that the degradation dynamics of sodium metal‐electrolyte interface are different for more concentrated (>2 M) electrolytes, suggesting that the higher concentration regime (above the conventional 1 M concentration) may be beneficial to battery performance. [ABSTRACT FROM AUTHOR]

Published

2021