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首页> 外文期刊>Advanced Functional Materials >Size-Controlled Synthesis of Cu_(2-x)E (E = S, Se) Nanocrystals with Strong Tunable Near-Infrared Localized Surface Plasmon Resonance and High Conductivity in Thin Films
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Size-Controlled Synthesis of Cu_(2-x)E (E = S, Se) Nanocrystals with Strong Tunable Near-Infrared Localized Surface Plasmon Resonance and High Conductivity in Thin Films

机译:Cu_(2-x)E(E = S,Se)纳米晶体的尺寸控制合成,薄膜中具有强可调谐的近红外局部表面等离子体激元共振和高电导率

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摘要

A facile method for preparing highly self-doped Cu_(2-x) (E = S, Se) nanocrystals (NCs) with controlled size in the range of 2.8-13.5 nm and 7.2-16.5 nm, for Cu_(2-x)S and Cu_(2-x)Se, respectively, is demonstrated. Strong near-infrared localized surface plasmon resonance absorption is observed in the NCs, indicating that the as-prepared particles are heavily p-doped. The NIR plasmonic absorption is tuned by varying the amount of oleic acid used in synthesis. This effect is attributed to a reduction in the number of free carriers through surface interaction of the deprotonated carboxyl functional group of oleic acid with the NCs. This approach provides a new pathway to control both the size and the cationic deficiency of Cu_(2-x)Se and Cu_(2-x)S NCs. The high electrical conductivity exhibited by these NPs in metal-semiconductor-metal thin film devices shows promise for applications in printable field-effect transistors and microelectronic devices.
机译:一种用于制备高度自掺杂的Cu_(2-x)的高度自掺杂的Cu_(2-x)(E = S,Se)纳米晶体(NCs)的简便方法,尺寸控制在2.8-13.5 nm和7.2-16.5 nm之间分别说明了S和Cu_(2-x)Se。在NC中观察到强烈的近红外局部表面等离子体激元共振吸收,表明所制备的颗粒是重p掺杂的。通过改变合成中使用的油酸量可以调节NIR等离子体吸收。这种作用归因于通过油酸的去质子化的羧基官能团与NC的表面相互作用减少了自由载流子的数量。该方法提供了控制Cu_(2-x)Se和Cu_(2-x)S NCs的尺寸和阳离子缺陷的新途径。这些NP在金属半导体金属薄膜器件中表现出的高电导率显示了在可印刷场效应晶体管和微电子器件中的应用前景。

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  • 来源
    《Advanced Functional Materials》 |2013年第10期|1256-1264|共9页
  • 作者

    Xin Liu; Xianliang Wang; Bin Zhou; Wing-Cheung Law; Alexander N. Cartwright; Mark T.Swihart;

  • 作者单位

    Department of Chemical and Biological Engineering University at Buffalo (SUNY) Buffalo, NY 14260. USA;

    Department of Chemical and Biological Engineering University at Buffalo (SUNY) Buffalo, NY 14260. USA;

    Department of Electrical Engineering University at Buffalo (SUNY) Buffalo, NY 14260. USA;

    Institute for Lasers Photonics, and Biophotonics University at Buffalo (SUNY) Buffalo, NY 14260. USA;

    Department of Electrical Engineering University at Buffalo (SUNY) Buffalo, NY 14260. USA;

    Department of Chemical and Biological Engineering University at Buffalo (SUNY) Buffalo, NY 14260. USA;

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