Ion Transport Kinetics in Low‐Temperature Lithium Metal Batteries

Hu, Anjun; Li, Fēi; Chen, Wei; Lei, Tianyu; Li, Yaoyao; Fan, Yuxin; He, Miao; Wang, Fan; Zhou, Mingjie; Hu, Yin; Yan, Yan; Chen, Bin; Zhu, Jing; Long, Jianping; Wang, Xianfu; Xiong, Jie

doi:10.1002/aenm.202202432

Cited by 109 publications

(44 citation statements)

References 140 publications

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“…Low ambient temperature causes a significant cell resistance and polarization, leading to a lower state of charge (SOC, defined in %, where 100% means the maximum number of Li + that can be fully reversibly intercalated or de-intercalated in the applied voltage region) of electrodes, and causing a significant decrease of the capacity and faster degradation upon continuous cycling [28,29]. The increased resistance at low temperatures is believed to be mainly associated with the changed migration behavior of Li + at each battery component, including electrolyte, electrodes, and electrode-electrolyte interphases [21,26]. Being a Li + conducting medium, high-freezing-point electrolyte remains the main rate-limiting factor for different LIB systems at low temperatures.…”

Section: Essential Problems Affecting the Lib Performance At Low Temp...mentioning

confidence: 99%

“…Piao et al focused more on heating techniques and thermal management to control the external reaction temperature [21]. The most recent reviews dissected the Li + transport/diffusion in electrolyte, solid electrode and their interphase, temperature-dependent limitating factors and challenges of lithium batteries, and offered their strategies to make an improvement [22][23][24][25][26][27].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Lithium-ion batteries for low-temperature applications: Limiting factors and solutions

Belgibayeva

Rakhmetova

Rakhatkyzy

et al. 2023

Journal of Power Sources

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Section: Essential Problems Affecting the Lib Performance At Low Temp...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Lithium-ion batteries for low-temperature applications: Limiting factors and solutions

Belgibayeva

Rakhmetova

Rakhatkyzy

et al. 2023

Journal of Power Sources

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“…The speed of ion transport in the interfacial layer is the key to uniform deposition, which affects the overall performance of Zn metal anode. [18] Some studies have shown that dendrite growth is inhibited when electrolytes with higher ionic conductivity and higher migration number are used. [15a,19] Uneven deposition is the beginning of a vicious cycle and dendrites growth.…”

Section: Principle I: Fast Ion Conduction Uniform Ion Fluxmentioning

confidence: 99%

Guiding Principles for the Design of Artificial Interface Layer for Zinc Metal Anode

Guo

Fan

Wu³

et al. 2022

Batteries & Supercaps

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Zinc-ion battery has become a research hotspot in the energy storage field due to its low cost, high safety, and environmental friendliness. However, zinc as an anode has some problems such as dendrites and hydrogen evolution on the surface, which hinder the practical application of zinc. These problems are closely related to the platting and stripping behavior of zinc at the electrode interface. The construction of an artificial interface layer is one of the most direct and effective methods to protect the zinc anode, which is helpful to improve the cycle life and utilization of the zinc anode. Here, we systematically review the progress and practical significance of artificial interfacial layers in terms of uniform ion transport, inhibition of side reactions and mechanical stability. Three design principles of the artificial interface layer are summarized to guide the further research, and to bring enlightenment for the construction of practical and efficient metal zinc anode.

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“…The implementation of small amount of FEC in the solvation structure increases ion carrier concentration and Li + transport channels in the SEI, as creating more inorganic compounds and grain boundaries [2b,14] . Therefore, sufficient Li + flux in the bulk electrolyte and fast charge‐transfer in the SEI, being inherent in this electrolyte design, are effective to resolve the low‐temperature limiting factor of the LMA [5a,10] . With these properties of our LHCE, the LMA could obtain substantially improved Li deposition morphology and plating/stripping stability from room temperature (RT) to −40 °C.…”

Section: Introductionmentioning

confidence: 99%

Tailored Solvation and Interface Structures by Tetrahydrofuran‐Derived Electrolyte Facilitates Ultralow Temperature Lithium Metal Battery Operations

Kim

Pol

2023

ChemSusChem

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Ineffectiveness of Li‐ion batteries (LIBs) in cold climates hinders electronics to work in various conditions including frigid environments, despite high demands. Given that intrinsic properties of LIB materials cause this problem, optimized cell chemistries ultimately are required for low‐temperature usage. In this study, Li‐metal batteries (LMBs) composed of a Li‐metal anode (LMA) stabilized by a localized high‐concentration electrolyte (LHCE) are found to significantly enhance low‐temperature performance. The LHCE allows the LMA to have compact and regular deposition and excellent plating/stripping efficiency at sub‐zero temperatures. The LHCE produces an inorganic‐rich solid‐electrolyte interphase with larger amounts of Li2O/LiF interfaces, dominance of ion aggregates in Li+ solvation, and enhanced Li+ transport, which can greatly improve the LMA stability. LMB full cells based on LiNi0.8Co0.1Mn0.1O2 cathodes with the tailored electrolyte show high retentions of 75 and 64 % at −20 and −40 °C, respectively. Furthermore, the LMB configuration retains its charge−discharge capability even at −60 °C.

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Ion Transport Kinetics in Low‐Temperature Lithium Metal Batteries

Cited by 109 publications

References 140 publications

Lithium-ion batteries for low-temperature applications: Limiting factors and solutions

Lithium-ion batteries for low-temperature applications: Limiting factors and solutions

Guiding Principles for the Design of Artificial Interface Layer for Zinc Metal Anode

Tailored Solvation and Interface Structures by Tetrahydrofuran‐Derived Electrolyte Facilitates Ultralow Temperature Lithium Metal Battery Operations

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