Weakening Li<sup>+</sup>De‐solvation Barrier for Cryogenic Li–S Pouch Cells

Ji, Haoqing; Wang, Zhenkang; Sun, Ya-Wen; Zhou, Yang; Li, Sijie; Zhou, Jinqiu; Qian, Tao; Yan, Chenglin

doi:10.1002/adma.202208590

Cited by 45 publications

(32 citation statements)

References 40 publications

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“…Many literatures have proposed that the de-solvation barriers of solvated ions at the interface of the electrode/electrolyte under low temperature is the main obstacle for achieving good low-temperature performance. [49][50][51] Therefore, it can be deduced that excellent electrochemical performance of COP/Cu@Zn anode at low temperature is due to desolvation of Zn ion under the help of COP layer. In a word, effect of COP layer in realizing de-solvation of Zn ion and regulating Zn deposit ensures high reversibility of COP/Cu@Zn anode.…”

Section: Resultsmentioning

confidence: 99%

Excluding the Trouble from Interfacial Water by Covalent Organic Polymer to Realize Extremely Reversible Zn Anode

Zhou

et al. 2023

Adv Funct Materials

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The side reactions related to water are the major issue hindering practical application of Zn metal batteries. To exclude the trouble from interfacial water, a covalent organic polymer (COP) layer with N, N′‐Bis(salicylidene)ethylenediamine structure is designed, whose strong coordination ability with Zn2+ enhances the de‐solvation kinetics of solvated Zn2+ which is conducive to interfacial water removal thus alleviating the side reactions related to water. This function has been certified by density functional theory along with molecular dynamics analysis. Moreover, measurements including in situ electrochemical gas chromatography, in situ optical microscopy, in situ X‐ray diffraction and in situ Raman spectroscopy verify the weakened side reactions (including hydrogen evolution and corrosion) along with homogenous Zn deposition contributed from the covalent organic polymer layer. Benefiting from these merits, when assemble into cells based on common ZnSO4‐based aqueous electrolyte, the COP layer‐decorated anode exhibits excellent electrochemical performance of a high average Coulombic efficiency value 99.5% at a high capacity of 5.0 mA h cm−2. What's more, the symmetric cells can operate at −20 °C and the full cell with N/P ratio as low as 1.2 can cycle stably for 100 cycles, which would carry forward the promising practical application of Zn metal batteries.

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Section: Resultsmentioning

confidence: 99%

Excluding the Trouble from Interfacial Water by Covalent Organic Polymer to Realize Extremely Reversible Zn Anode

Zhou

et al. 2023

Adv Funct Materials

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“…Specically, solvent molecules explicitly bond with solutes, and the (de)solvation energy would be distinct when solutes are coordinated by different numbers of solvents, namely in different solvation statuses (e.g., non-solvated, partially solvated, and fully solvated). [35][36][37] Lin et al found that varying the concentration of electrolytes results in different solvation statuses of poly-suldes, thus signicantly affecting the open circuit voltage of batteries. 38 Whether the solvation statuses of sulfur species affect the generation of trisulfur radicals is worthy of in-depth exploration.…”

Section: $àmentioning

confidence: 99%

“…, non-solvated, partially solvated, and fully solvated). 35–37 Lin et al found that varying the concentration of electrolytes results in different solvation statuses of polysulfides, thus significantly affecting the open circuit voltage of batteries. 38 Whether the solvation statuses of sulfur species affect the generation of trisulfur radicals is worthy of in-depth exploration.…”

Section: Introductionmentioning

confidence: 99%

Mechanistic insights into trisulfur radical generation in lithium–sulfur batteries

Han¹,

Xu²

2023

J. Mater. Chem. A

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“…In addition, the advantages of sulfur, which has low cost, is easily available, and environmentally friendly, have also attracted wide attentions. [5][6][7][8] However, The 'shuttle effect' and lithium anode corrosion have always restricted the development of Li-S batteries. During the charging and discharging process, the soluble lithium polysulfides (Li 2 S x , 2 < x ≤ 8) are formed and dissolved in the electrolyte, resulting in the loss of active sulfur and corrosion of lithium anodes, which leads to the sharp capacity decline and poor safety performance.…”

Section: Introductionmentioning

confidence: 99%

A Separator with Double Coatings of Li₄Ti₅O₁₂and Conductive Carbon for Li‐S Battery of Good Electrochemical Performance

et al. 2023

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The market demand for energy pushes researchers to pay a lot of attention to Li-S batteries. However, the 'shuttle effect', the corrosion of lithium anodes, and the formation of lithium dendrites make the poor cycling performances (especially under high current densities and high sulfur loading) of Li-S batteries, which limit their commercial applications. Here, a separator is prepared and modified with Super P and LTO (abbreviation SPLTOPD) through a simple coating method. The LTO can improve the transport ability of Li + cations, and the Super P can reduce the charge transfer resistance. The prepared SPLTOPD can effectively barrier the pass-through of polysulfides, catalyze the reactions of polysulfides into S 2− , and increase the ionic conductivity of the Li-S batteries. The SPLTOPD can also prevent the aggregation of insulating sulfur species on the surface of the cathode. The assembled Li-S batteries with the SPLTOPD can cycle 870 cycles at 5 C with the capacity attenuation of 0.066% per cycle. When the sulfur loading is up to 7.6 mg cm −2 , the specific discharge capacity at 0.2 C can reach 839 mAh g −1 , and the surface of lithium anode after 100 cycles does not show the existence lithium dendrites or a corrosion layer. This work provides an effective way for the preparation of commercial separators for Li-S batteries.

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Weakening Li⁺De‐solvation Barrier for Cryogenic Li–S Pouch Cells

Cited by 45 publications

References 40 publications

Excluding the Trouble from Interfacial Water by Covalent Organic Polymer to Realize Extremely Reversible Zn Anode

Excluding the Trouble from Interfacial Water by Covalent Organic Polymer to Realize Extremely Reversible Zn Anode

Mechanistic insights into trisulfur radical generation in lithium–sulfur batteries

A Separator with Double Coatings of Li₄Ti₅O₁₂and Conductive Carbon for Li‐S Battery of Good Electrochemical Performance

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Weakening Li+De‐solvation Barrier for Cryogenic Li–S Pouch Cells

Cited by 45 publications

References 40 publications

Excluding the Trouble from Interfacial Water by Covalent Organic Polymer to Realize Extremely Reversible Zn Anode

Excluding the Trouble from Interfacial Water by Covalent Organic Polymer to Realize Extremely Reversible Zn Anode

Mechanistic insights into trisulfur radical generation in lithium–sulfur batteries

A Separator with Double Coatings of Li4Ti5O12and Conductive Carbon for Li‐S Battery of Good Electrochemical Performance

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Weakening Li⁺De‐solvation Barrier for Cryogenic Li–S Pouch Cells

A Separator with Double Coatings of Li₄Ti₅O₁₂and Conductive Carbon for Li‐S Battery of Good Electrochemical Performance