半导体ZnO纳米带的电流-电压和光电子特性

2006 1st IEEE International Conference on Nano/Micro Engineered and Molecular Systems Pub Date : 2006-01-01 DOI:10.1109/NEMS.2006.334903

Dingqu Wang, R. Zhu, Zhaoying Zhou, X. Ye

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引用次数: 1

摘要

我们报道了ZnO纳米带束的电泳排列及其电学和光学性质。利用频率为5 ~ 50 MHz、峰间振幅为2 ~ 20 V的交流电流将纳米带捕获到一对电极上。在室温空气环境下，利用氙弧光源研究了它们与光电相关的电输运特性。观察到三种典型的静脉特征:不对称、对称和无限阻抗。光电导率测量表明，ZnO纳米带的光电流随着光强的1.6倍而增加。在-3V的偏置电压下，电子浓度δ n估计为3.3倍107 cm-1。通过光响应实验研究了光电流衰减，估计其衰减时间约为3 s。总的来说，ZnO纳米带被证明是一种非凡的光电材料，在纳米级光子器件中具有广泛的应用。

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Current-voltage and Optoelectronic Properties of Semiconducting ZnO Nanobelts

We report on electrophoretic alignment of ZnO nanobelt bunches and their electrical and optical properties. The nanobelts were trapped onto a pair of electrodes by using alternating electrical current at frequency between 5 ~ 50 MHz and peak-to-peak amplitude from 2 to 20 V. Their electrical transport properties associated with the photoelectricity were studied at room temperature in the air ambient by using a xenon arc lamp source. Three typical IV characteristics were observed: asymmetry, symmetry and infinite impedance. The photoconductivity measurements show that the photocurrent through ZnO nanobelts increases as about 1.6 power of light intensity. The electron concentration Delta n is estimated to be 3.3times107 cm-1 at a bias voltage of -3V. Photocurrent decay was also studied through the experiment of photoresponse to illumination, and the decay time was estimated to be about 3 s. Collectively, ZnO nanobelts are demonstrated to be a remarkable optoelectronic material that holds wide applications for nanoscale photonic devices.

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2006 1st IEEE International Conference on Nano/Micro Engineered and Molecular Systems

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