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首页> 外文期刊>ACS applied materials & interfaces >Updating the Intrinsic Activity of a Single-Atom Site with a P-O Bond for a Rechargeable Zn-Air Battery
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Updating the Intrinsic Activity of a Single-Atom Site with a P-O Bond for a Rechargeable Zn-Air Battery

机译:更新单原子网站的固有活动,并为可充电Zn-Air电池的P-O键合

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摘要

Rechargeable Zn-air batteries have drawn great attention over the past decade, but their further development will require efficient bifunctional electrocatalysts to drive the sluggish cathodic reactions. Although a single-atom catalyst with maximum utilization per metal atom shows great promise, its catalytic performance is still far from satisfactory. Here we tackle this challenge by introducing a P-O bond to update the intrinsic activity of a single-atom site and thus reduce the reaction overpotential of the Zn-air battery. The critical role of the P-O bond in producing a favorable surface electronic environment of the single-atom metal site and improving its catalytic activity is identified with density functional theory simulations. The P-O-doped, atomically dispersed catalyst is shown experimentally to deliver excellent bifunctional performance, with a remarkable half-wave potential of 0.89 V versus reversible hydrogen electrode (vs RHE) for oxygen reduction reaction and a reversible oxygen electrode index of 0.74 V, exceeding those of most reported nonprecious metal catalysts. When subjected to practical application, both aqueous and all-solid-state Zn-air batteries illustrate superior power density and robust cyclic performance, confirming their potential feasibility in next-generation electronic devices.
机译:可充电的Zn-Air电池在过去十年中引起了很大的关注,但他们的进一步发展将需要高效的双官能电催化剂来驱动缓慢的阴极反应。虽然每金金属原子最大利用的单个原子催化剂显示出很大的希望,但其催化性能仍然远非令人满意。在这里,我们通过引入P-O键来更新单个原子位点的内在活动,从而减少Zn空气电池的反应来解决这一挑战。 P-O键在单原子金属位点产生有利表面电子环境中的关键作用,并用密度泛函理论模拟鉴定出改善其催化活性。通过实验示出了Po掺杂的原子分散催化剂以提供优异的双官能性能,其具有0.89V的显着半波电位与可氧还原反应的可逆氢电极(VS RHE),并且可逆氧电极指数为0.74V,超过最多报道的非普烈金属催化剂的那些。当经过实际应用时,水和全固态Zn空气电池都采用了优异的功率密度和坚固的循环性能,确认其在下一代电子设备中的潜在可行性。

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  • 来源
    《ACS applied materials & interfaces》 |2019年第36期|共8页
  • 作者

    Sun He; Liu Sisi; Wang Mengfan; Qian Tao; Xiong Jie; Yan Chenglin;

  • 作者单位

    Univ Elect Sci &

    Technol China State Key Lab Elect Thin Films &

    Integrated Devic Chengdu 610054 Sichuan Peoples R China;

    Soochow Univ Key Lab Adv Carbon Mat &

    Wearable Energy Technol Key Lab Adv Opt Mfg Technol Jiangsu Prov Coll Energy Suzhou 215006 Peoples R China;

    Soochow Univ Key Lab Adv Carbon Mat &

    Wearable Energy Technol Key Lab Adv Opt Mfg Technol Jiangsu Prov Coll Energy Suzhou 215006 Peoples R China;

    Soochow Univ Key Lab Adv Carbon Mat &

    Wearable Energy Technol Key Lab Adv Opt Mfg Technol Jiangsu Prov Coll Energy Suzhou 215006 Peoples R China;

    Univ Elect Sci &

    Technol China State Key Lab Elect Thin Films &

    Integrated Devic Chengdu 610054 Sichuan Peoples R China;

    Soochow Univ Key Lab Adv Carbon Mat &

    Wearable Energy Technol Key Lab Adv Opt Mfg Technol Jiangsu Prov Coll Energy Suzhou 215006 Peoples R China;

  • 收录信息
  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类 化学工业;
  • 关键词

    single-atom catalyst; P-O bond; oxygen reduction reaction; Zn-air battery; all-solid-state battery;

    机译:单原子催化剂;P-O键;氧还原反应;Zn-Air电池;全固态电池;

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