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Effect of boron/nitrogen co-doping on transport properties of C60 molecular devices

Effect of boron/nitrogen co-doping on transport properties of C60 molecular devices
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摘要 By using nonequilibrium Green's function method and first-principles calculations, the electronic transport properties of doped C60 molecular devices were investigated. It is revealed that the C60 molecular devices show the metal behavior due to the interaction between the C60 molecule and the metal electrode. The current-voltage curve displays a linear behavior at low bias, and the currents have the relation of MI〉M3〉M4〉M2 when the bias voltage is lower than 0.6 V. Electronic transport properties are affected greatly by the doped atoms. Negative differential resistance is found in a certain bias range for C60 and C58BN molecular devices, but cannot be observed in C59B and C59N molecular devices. These unconventional effects can be used to design novel nanoelectronic devices. By using nonequilibrium Green's function method and first-principles calculations, the electronic transport properties of doped C60 molecular devices were investigated. It is revealed that the C60 molecular devices show the metal behavior due to the interaction between the C60 molecule and the metal electrode. The current-voltage curve displays a linear behavior at low bias, and the currents have the relation of M1>M3>M4>M2 when the bias voltage is lower than 0.6 V. Electronic transport properties are affected greatly by the doped atoms. Negative differential resistance is found in a certain bias range for C60 and C58BN molecular devices, but cannot be observed in C59B and C59N molecular devices. These unconventional effects can be used to design novel nanoelectronic devices.
作者 伍晓赞 黄光辉 陶庆斌 徐慧
机构地区 School of Physical and Electronics School of Materials Science and Engineering
出处 《Journal of Central South University》 SCIE EI CAS 2013年第4期889-893,共5页 中南大学学报(英文版)
基金 Project(07JJ3102) supported by the Natural Science Foundation of Hunan Province, China Project(1343-74236000006) supported by the Graduate Foundation of Hunan Province, China Project(11MY20) supported by the Mittal Entrepreneurship Program of China
关键词 negative differential resistance molecular device electronic transport property first-principles calculation 电子输运性质 C60分子 分子器件 第一性原理计算 掺杂 合作 格林函数方法 偏置电压
分类号 O611.3 [理学—无机化学]
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参考文献25

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Journal of Central South University
2013年 第4期

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