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首页> 外文期刊>Advanced energy materials >Nano-Scale Complexions Facilitate Li Dendrite-Free Operation in LATP Solid-State Electrolyte
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Nano-Scale Complexions Facilitate Li Dendrite-Free Operation in LATP Solid-State Electrolyte

机译:纳米级梳理有助于LATP固态电解液中的Li Dentrite-Free

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摘要

Dendrite formation and growth remains a major obstacle toward high-performance all solid-state batteries using Li metal anodes. The ceramic Li(1+x)Al(x)Ti(2-x)(PO4)(3) (LATP) solid-state electrolyte shows a higher than expected stability against electrochemical decomposition despite a bulk electronic conductivity that exceeds a recently postulated threshold for dendrite-free operation. Here, transmission electron microscopy, atom probe tomography, and first-principles based simulations are combined to establish atomistic structural models of glass-amorphous LATP grain boundaries. These models reveal a nanometer-thin complexion layer that encapsulates the crystalline grains. The distinct composition of this complexion constitutes a sizable electronic impedance. Rather than fulfilling macroscopic bulk measures of ionic and electronic conduction, LATP might thus gain the capability to suppress dendrite nucleation by sufficient local separation of charge carriers at the nanoscale.
机译:树突式形成和生长仍然是使用Li金属阳极的高性能所有固态电池的主要障碍。 陶瓷Li(1 + X)Al(X)Ti(2-X)(PO4)(3)(LatP)固态电解质显示出高于电化学分解的预期稳定性,尽管超过最近假设的散装电子电导率 树突操作的阈值。 这里,透射电子显微镜,原子探测层析造影和基于第一原理的模拟,以建立玻璃 - 无定形拉特晶界的原子结构模型。 这些模型显示了一种纳米薄的络合层,其封装了结晶颗粒。 这种络合的独特组成构成了可相同的电子阻抗。 Latp不能满足离子和电子传导的宏观散装措施,因此LATP可以通过在纳米级上充分局部分离载流子的充分局部分离来获得抑制树突成核的能力。

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  • 来源
    《Advanced energy materials》 |2021年第26期|2100707.1-2100707.10|共10页
  • 作者

    Stegmaier Sina; Schierholz Roland; Povstugar Ivan; Barthel Juri; Rittmeyer Simon P.; Yu Shicheng; Wengert Simon; Rostami Samare; Kungl Hans; Reuter Karsten; Eichel Rudiger-A.; Scheurer Christoph;

  • 作者单位

    Tech Univ Munich Chair Theoret Chem D-85747 Garching Germany|Tech Univ Munich Catalysis Res Ctr D-85747 Garching Germany;

    Forschungszentrum Julich Inst Energy & Climate Res Fundamental Electrochem D-52425 Julich Germany;

    Forschungszentrum Julich Cent Inst Engn Elect & Analyt ZEA 3 D-52428 Julich Germany;

    Forschungszentrum Julich Ernst Ruska Ctr Microscopy & Spect Electron ER C D-52428 Julich Germany;

    Tech Univ Munich Chair Theoret Chem D-85747 Garching Germany|Tech Univ Munich Catalysis Res Ctr D-85747 Garching Germany;

    Forschungszentrum Julich Inst Energy & Climate Res Fundamental Electrochem D-52425 Julich Germany;

    Max Planck Gesell Fritz Haber Inst Theory Dept D-14195 Berlin Germany;

    Tech Univ Munich Chair Theoret Chem D-85747 Garching Germany|Tech Univ Munich Catalysis Res Ctr D-85747 Garching Germany;

    Forschungszentrum Julich Inst Energy & Climate Res Fundamental Electrochem D-52425 Julich Germany;

    Tech Univ Munich Chair Theoret Chem D-85747 Garching Germany|Tech Univ Munich Catalysis Res Ctr D-85747 Garching Germany|Max Planck Gesell Fritz Haber Inst Theory Dept D-14195 Berlin Germany;

    Forschungszentrum Julich Inst Energy & Climate Res Fundamental Electrochem D-52425 Julich Germany|Rhein Westfal TH Aachen Inst Phys Chem D-52074 Aachen Germany;

    Tech Univ Munich Chair Theoret Chem D-85747 Garching Germany|Tech Univ Munich Catalysis Res Ctr D-85747 Garching Germany|Max Planck Gesell Fritz Haber Inst Theory Dept D-14195 Berlin Germany;

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  • 正文语种 eng
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  • 关键词

    atom probe tomography; dendrites; density functional theory; molecular dynamics; transmission electron microscopy;

    机译:原子探测断层扫描;树突;密度函数理论;分子动力学;透射电子显微镜;

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