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首页> 外文期刊>Advanced energy materials >Pyrrolidinium-PEG Ionic Copolyester: Li-Ion Accelerator in Polymer Network Solid-State Electrolytes
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Pyrrolidinium-PEG Ionic Copolyester: Li-Ion Accelerator in Polymer Network Solid-State Electrolytes

机译:Pyrrolidinium-PEG离子共聚酯:聚合物网络固态电解质中的锂离子促进剂

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摘要

Nonflammable lithium-ion batteries (LIBs) are developed by adapting polymer solid electrolytes, but their insufficient electrochemical performance has not been fully addressed to date. Crosslinked polymer gel electrolytes with minimal organic solvents (hard gels) are proven to be nonflammable electrolytes, but their lithium metal battery performance is not comparable to those of conventional liquid electrolyte-based systems. Here, a semi-interpenetrating polymer network (semi-IPN) ion-transporting solid film that comprises a UV-curable crosslinked polymer and tailored linear pyrrolidinium-polyethylene glycol copolyester ion channels (named P(N)PEG), is reported. P(N)PEG can solvate Li+ effectively with the help of carbonate solvents. Molecular dynamics (MD) simulations confirm that Li+ transportation is accelerated due to the weaker interaction between P(N)PEG and Li+ ions than between the solvents and ions. The semi-IPN electrolyte with P(N)PEG exhibits a flexible, nonflammable nature with an ionic conductivity of 4.2 x 10(-1) mS cm(-1) and Li+ transference number of 0.51. The individual pyrrolidinium-Bis(trifluoromethanesulfonyl)imide (pyrrolidinium-Tf2N) monomer and PEG chain ratios in P(N)PEG strongly affect battery performance, and the optimized semi-IPN-based lithium metal half cells with LiCoO2 cathodes show greatly improved discharge capacity retention at high c-rate conditions owing to effective Li+ transportation and excellent cycling performance (93.8% capacity retention after 200 cycles at 0.5 C).
机译:不易燃锂离子电池(LIBS)通过适应聚合物固体电解质而开发,但它们的电化学性能不足迄今尚未完全解决。已证明具有最小有机溶剂(硬凝胶)的交联聚合物凝胶电解质是不可燃的电解质,但它们的锂金属电池性能与常规液体电解质的系统不相媲美。这里,报道了半互持聚合物网络(半IPN)离子传输的固体膜,其包含UV可固化的交联聚合物和定制的线性吡咯烷鎓 - 聚乙二醇共聚酯离子通道(命名为P(n)PEG)。 P(n)PEG可以在碳酸盐溶剂的帮助下有效地溶剂化Li +。分子动力学(MD)模拟证实,由于P(n)PEG和Li +离子之间的相互作用较弱,Li +输送量被加速,而不是溶剂和离子之间的相互作用。具有P(n)PEG的半IPn电解质表现出柔性的不易燃性质,其离子电导率为4.2×10(-1)mscm(-1)和Li +转移数为0.51。 P(n)PEG中的单独的吡咯烷 - 双(三氟甲磺酰基)酰亚胺(吡咯烷磺酰基)酰亚胺(吡咯烷-TF2N)单体和PEG链比强烈影响电池性能,以及具有LiCoO2阴极的优化的半IPN基锂金属半电池显示出大大提高的放电容量由于有效的Li +运输和优异的循环性能(在0.5℃下为200次循环后93.8%的容量保留93.8%的循环潴留)保持高C速率条件。

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  • 来源
    《Advanced energy materials》 |2021年第44期|2102660.1-2102660.9|共9页
  • 作者

    Choi Young Gyun; Shin Jong Chan; Park Anseong; Jeon Young Min; Kim Jin Il; Kim Sebin; Kim Seulwoo; Lee Won Bo; Lee Minjae; Park Jong Hyeok;

  • 作者单位

    Yonsei Univ Dept Chem & Biomol Engn 50 Yonsei Ro Seoul 03722 South Korea;

    Kunsan Natl Univ Dept Chem 558 Daehak Ro Gunsan 54150 Jeollabuk Do South Korea;

    Seoul Natl Univ Sch Chem & Biol Engn 1 Gwanak Ro Seoul 08826 South Korea|Seoul Natl Univ Inst Chem Proc 1 Gwanak Ro Seoul 08826 South Korea;

    Yonsei Univ Dept Chem & Biomol Engn 50 Yonsei Ro Seoul 03722 South Korea;

    Yonsei Univ Dept Chem & Biomol Engn 50 Yonsei Ro Seoul 03722 South Korea;

    Seoul Natl Univ Sch Chem & Biol Engn 1 Gwanak Ro Seoul 08826 South Korea|Seoul Natl Univ Inst Chem Proc 1 Gwanak Ro Seoul 08826 South Korea;

    Seoul Natl Univ Sch Chem & Biol Engn 1 Gwanak Ro Seoul 08826 South Korea|Seoul Natl Univ Inst Chem Proc 1 Gwanak Ro Seoul 08826 South Korea;

    Seoul Natl Univ Sch Chem & Biol Engn 1 Gwanak Ro Seoul 08826 South Korea|Seoul Natl Univ Inst Chem Proc 1 Gwanak Ro Seoul 08826 South Korea;

    Kunsan Natl Univ Dept Chem 558 Daehak Ro Gunsan 54150 Jeollabuk Do South Korea;

    Yonsei Univ Dept Chem & Biomol Engn 50 Yonsei Ro Seoul 03722 South Korea;

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  • 正文语种 eng
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  • 关键词

    ion accelerators; ionic copolyester; lithium-ion batteries; polymer electrolytes; solid electrolytes;

    机译:离子促进剂;离子共聚酯;锂离子电池;聚合物电解质;固体电解质;

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