Influence of self-heating on the millimeter-wave and terahertz performance of MBE grown silicon IMPATT diodes

Influence of self-heating on the millimeter-wave and terahertz performance of MBE grown silicon IMPATT diodes

在线阅读下载PDF

导出

摘要 The influence of self-heating on the millimeter-wave(mm-wave)and terahertz(THz)performance of double-drift region(DDR)impact avalanche transit time(IMPATT)sources based on silicon(Si)has been investigated in this paper.The dependences of static and large-signal parameters on junction temperature are estimated using a non-sinusoidal voltage excited(NSVE)large-signal simulation technique developed by the authors,which is based on the quantum-corrected drift-diffusion(QCDD)model.Linear variations of static parameters and non-linear variations of large-signal parameters with temperature have been observed.Analytical expressions representing the temperature dependences of static and large-signal parameters of the diodes are developed using linear and 2nd degree polynomial curve fitting techniques,which will be highly useful for optimizing the thermal design of the oscillators.Finally,the simulated results are found to be in close agreement with the experimentally measured data. The influence of self-heating on the millimeter-wave(mm-wave) and terahertz(THz) performance of double-drift region(DDR) impact avalanche transit time(IMPATT) sources based on silicon(Si) has been investigated in this paper. The dependences of static and large-signal parameters on junction temperature are estimated using a non-sinusoidal voltage excited(NSVE) large-signal simulation technique developed by the authors, which is based on the quantum-corrected drift-diffusion(QCDD) model. Linear variations of static parameters and non-linear variations of large-signal parameters with temperature have been observed. Analytical expressions representing the temperature dependences of static and large-signal parameters of the diodes are developed using linear and 2 nd degree polynomial curve fitting techniques, which will be highly useful for optimizing the thermal design of the oscillators. Finally, the simulated results are found to be in close agreement with the experimentally measured data.

作者 S.J.Mukhopadhyay Prajukta Mukherjee Aritra Acharyya Monojit Mitra

机构地区 Department of Electronics and Telecommunication Engineering Department of Electrical Engineering Department of Electronics and Communication Engineering

出处《Journal of Semiconductors》 EI CAS CSCD 2020年第3期13-22,共10页 半导体学报（英文版）

关键词 IMPATT oscillators linear temperature coefficient SELF-HEATING thermal runway quadratic temperature coefficient IMPATT oscillators linear temperature coefficient self-heating thermal runway quadratic temperature coefficient

分类号 TN31 [电子电信—物理电子学]

作者简介 Correspondence to:Aritra Acharyya,ari_besu@yahoo.co.in。

引文网络
相关文献

参考文献1

1Aritra Acharyya,Suranjana Banerjee,J.P.Banerjee.Effect of junction temperature on the large-signal properties of a 94 GHz silicon based double-drift region impact avalanche transit time device[J].Journal of Semiconductors,2013,34(2):19-30. 被引量：6

二级参考文献27

1Midford T A, Bemick R L. Millimeter wave CW IMPATT diodes and oscillators. IEEE Trans Microw Theory Tech, 1979, 27:483.
2Chang Y, Hellum J M, Paul J A, et al. Millimeter-wave 1MPATT sources for communication applications. IEEE MTT-S Interna- tional Microwave Symposium Digest, 1977:216.
3Gray W W, Kikushima L, Morentc N P, et al. Applying IMPATT power sources to modem microwave systems. IEEE J Solid-State Circuits, 1969, 4:409.
4Miswa T. Negative resistance in p-n junctions under avalanche breakdown conditions. IEEE Trans Electron Devices, 1966, 33: 137.
5Gilden M, Hines M E. Electronic tuning effects in the read mi- crowave avalanche diode. IEEE Trans Electron Devices, 1966, 13(1): 169.
6Gummel H K, Scharfetter D L. Avalanche region of IMPATT diodes. Bell Sys Tech J, 1966, 45:1797.
7Evans W J, Haddad G I. A large-signal analysis of IMPATT diodes. IEEE Trans Electron Devices, 1968, 15(10): 708.
8Scharfetter D L, Gummel H K. Large-signal analysis of a silicon read diode oscillator. IEEE Trans Electron Devices, 1969, 6(1): 64.
9Gupta M S, Lomax R J. A current-excited large-signal analysis of IMPATT devices and its circuit implementations. IEEE Trans Electron Devices, 1973, 20:395.
10Roy S K, Sridharan M, Ghosh R, et al. Computer method for the dc field and carrier current profiles in the IMPATT device starting from the field extremum in the depletion layer. In: Miller J H, ed. Proceedings of the 1st Conference on Numerical Analysis of Semiconductor Devices (NASECODE I), Dublin, Ireland, 1979: 266.

共引文献5

1Aritra Acharyya,Jit Chakraborty,Kausik Das,Subir Datta,Pritam De,Suranjana Banerjee,J.P.Banerjee.Large-signal characterization of DDR silicon IMPATTs operating in millimeter-wave and terahertz regime[J].Journal of Semiconductors,2013,34(10):46-53. 被引量：2
2王志斌,孔亚楠,刘永成,张骞.遗传算法优化BP神经网络的大功率LED结温预测[J].光电子．激光,2014,25(7):1303-1309. 被引量：24
3Aritra Acharyya,Aliva Mallik,Debopriya Banerjee,Suman Ganguli,Arindam Das,Sudeepto Dasgupta,J.P.Banerjee.Large-signal characterizations of DDR IMPATT devices based on group Ⅲ–Ⅴ semiconductors at millimeter-wave and terahertz frequencies[J].Journal of Semiconductors,2014,35(8):69-78. 被引量：2
4Aritra Acharyya.Hot electron transport in wurtzite-GaN:effects of temperature and doping concentration[J].Journal of Semiconductors,2018,39(7):48-53.
5李秀圣,曹连振.In0.17Al0.83N/GaN IMPATT二极管的温度特性[J].半导体技术,2020,45(12):936-942.

1Janmejaya Pradhan,S K Swain,S R Pattnaik,G N Dash.Potentials of GaP as millimeter wave IMPATT diode with reference to Si,GaAs and GaN[J].红外与毫米波学报,2019,38(4):395-402. 被引量：3
2Pranati Panda,Satya Narayana Padhi,Gana Nath Dash.High Efficiency SiC Terahertz Source in Mixed Tunnelling Avalanche Transit Time Mode[J].World Journal of Nano Science and Engineering,2014,4(4):143-150.
3Chuanhai Gao,Menglun Zhang,Yuan Jiang.FlexMEMS-enabled hetero-integration for monolithic FBAR-above-IC oscillators[J].Nanotechnology and Precision Engineering,2019,2(3):105-109. 被引量：1
4Emil Edipovich Lin.On Boundaries of Cosmos[J].World Journal of Mechanics,2015,5(1):1-6.
5FARHAN Masood,XUE Yixuan',ZHEN Ziyang,YANG Liuqing.H_∞ Preview Control for Automatic Carrier Landing[J].Transactions of Nanjing University of Aeronautics and Astronautics,2019,36(6):919-926. 被引量：2
6李应求,周姬,周学忠.基于Box-Cox变换的水位流量关系拟合[J].长江科学院院报,2020,37(1):18-21. 被引量：6
7曹斌,潘兰萍,蒋柏枫,邓振兴,陈玉红.急性心肌梗死患者冠状动脉内推注硝普钠防治慢血流或无复流有效性的Meta分析[J].岭南心血管病杂志,2020,26(1):16-18. 被引量：3
8Z.Y.Liu,T.L.Jiang,L.Wang,H.L.Dai.Nonplanar flow-induced vibrations of a cantilevered PIP structure system concurrently subjected to internal and cross flows[J].Acta Mechanica Sinica,2019,35(6):1241-1256. 被引量：5
9王超帅,仇怀利,李思寒,张栋,沈周阳,李中军.TiO2/Bi2Se3复合材料的制备及光电化学性能[J].半导体技术,2020,45(1):52-57. 被引量：1
10吴奇志.穆谦:让世界了解中国传统音乐[J].今日中国,2020,69(3):70-73.

Journal of Semiconductors

2020年第3期

浏览历史

内容加载中请稍等...

Influence of self-heating on the millimeter-wave and terahertz performance of MBE grown silicon IMPATT diodes

参考文献1

二级参考文献27

共引文献5

相关作者

相关机构

相关主题

浏览历史