太赫兹源场致发射电子源

通过粒子模拟(PIC)软件模拟计算了在ps级别下二极与三极结构碳纳米管场致发射的电流密度与电子注聚焦性能。阳极电压在2 kV时，二极结构下电流密度达到1.85 A/cm2;三极结构下，栅压700 V时发射电流密度达到2.3 A/cm2，且在一定的三极结构参数与电极电压下，可以获得较好的电子注聚束效果。通过碳纳米管二极管发射实验，获得了6.6 A/cm2的发射电流密度，总发射电流达到52.1 mA，可以为太赫兹器件提供连续发射的电子注。

Abstract

Field emission from carbon nanotube (CNT) has been simulated by a particle-in-cell (PIC) software at pico-second level. The emission current, current density and focus character of a CNT cathode have been discussed. In a diode configuration, the emission current from cathode reaches 1.85 A/cm2 when the anode voltage is 2 kV. While in a triode configuration, the current reaches 2.3 A/cm2 for a gate voltage of 700 V, and the focus performance of electron beam can be optimized by modifying triode parameters and voltage applied to the electrodes. A diode structure with CNT cathode has been fabricated to verify large-current field emission, a total emission current of 52.1 mA and a current density of 6.6 A/cm2 have been obtained from this diode. It proved that field emission cathode can be applied in terahertz source devices.

参考文献

[1] 刘维浩，张雅鑫，胡旻，等.基于场致发射阴极阵列的太赫兹源的物理机理研究［J］.物理学报， 2012, 61:127901.(Liu Weihao, Zhang Yaxin, Hu Min, et al. Mechanism study of a THz source using field emission array. Acta Physica Sinica, 2012, 61:127901)

[2] 谷智，陈沅，李焕勇，等.太赫兹辐射源的研究进展［J］.红外技术， 2011, 33(5):252-256.(Gu Zhi, Chen Yuan, Li Huanyong, et al. Research progress of terahertz radiation sources. Infrared Technology, 2011, 33(5):252-256)

[3] 杨鹏飞，姚建铨，邴丕彬.太赫兹波及其常用源［J］.激光与红外， 2011, 41(2):125-131.(Yang Pengfei, Yao Jianquan, Bin Pibin, et al. Source and characteristics of THz wave. Laser and Infrared, 2011, 41(2):125-131)

[4] 廖复疆.微型真空电子器件和太赫兹辐射源技术进展［J］.电子学报, 2003, 31(9):1361-1364.(Liao Fujiang. Micro-vacuum electron devices and terahertz vacuum sources. Acta Electron Sinica, 2003, 31(9):1361-1364)

[5] Wei Y, Jiang K L, Liu L, et al. Needle-shaped ends of multiwalled carbon nanotube yarns and their field emission applications［J］. Nano Lett, 2007, 7(12):3792-3797.

[6] Liu N, Fang G, Zeng W, et al. Diminish the screen effect in field emission via patterned and selective edge growth of ZnO nanorod arrays［J］. Appl Phys Lett, 2009, 95:153505.

[7] Ye D, Sherif M, Josephus D, et al. Highly efficient electron field emission from graphene oxide sheets supported by nickel nanotip arrays［J］. Nano Lett, 2012, 12:1265-1268.

[8] Lei W, Zhang X B, Chen J, et al. Veryhigh field emission from a carbon nanotube array with isolated subregions and balanced resistances［J］. IEEE Trans on Electron Dev, 2011, 58(10):3616-3621.

[9] 陈泽祥,曹贵川,张强,等.大电流密度碳纳米管场致发射阴极阵列的研制［J］.强激光与粒子束, 2006, 18(12):2070-2073.(Chen Zexiang, Cao Guichuan, Zhang Qiang, et al. Fabrication of large current density carbon nanotube based field emitters. High Power Laser and Particle Beams, 2006, 18(12):2070-2073)

狄云松, 张晓兵, 雷威, 章莉芳, 崔云康, 王琦龙, 陈静. 太赫兹源场致发射电子源[J]. 强激光与粒子束, 2013, 25(6): 1494. Di Yunsong, Zhang Xiaobing, Lei Wei, Zhang Lifang, Cui Yunkang, Wang Qilong, Chen Jing. Field emission electron source for terahertz source application[J]. High Power Laser and Particle Beams, 2013, 25(6): 1494.

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