Backgating effect in GaAs FETs with a channel–semi-insulating substrate boundary 被引量：1

Backgating effect in GaAs FETs with a channel–semi-insulating substrate boundary

导出

摘要 This study focuses on modeling the effects of deep hole traps, mainly the effect of the substrate（backgating effect） in a GaAs transistor MESFT. This effect is explained by the existence, at the interface, of a space charge zone. Any modulation in this area leads to response levels trapping the holes therein to the operating temperature. We subsequently developed a model treating the channel substrate interface as an N–P junction, allowing us to deduce the time dependence of the component parameters of the total resistance R ds, the pinch-off voltage V P, channel resistance, fully open R co and the parasitic series resistance R S to bind the effect trap holes H1and H0. When compared with the experimental results, the values of the R DS（t S/ model for both traps show that there is an agreement between theory and experiment; it has inferred parameter traps, namely the density and the time constant of the trap. This means that a space charge region exists at the channel–substrate interface and that the properties can be approximated to an N–P junction. This study focuses on modeling the effects of deep hole traps, mainly the effect of the substrate（backgating effect） in a GaAs transistor MESFT. This effect is explained by the existence, at the interface, of a space charge zone. Any modulation in this area leads to response levels trapping the holes therein to the operating temperature. We subsequently developed a model treating the channel substrate interface as an N–P junction, allowing us to deduce the time dependence of the component parameters of the total resistance R ds, the pinch-off voltage V P, channel resistance, fully open R co and the parasitic series resistance R S to bind the effect trap holes H1and H0. When compared with the experimental results, the values of the R DS（t S/ model for both traps show that there is an agreement between theory and experiment; it has inferred parameter traps, namely the density and the time constant of the trap. This means that a space charge region exists at the channel–substrate interface and that the properties can be approximated to an N–P junction.

作者 Ahmed Chaouki Megherbi Said Benramache Abderrazak Guettaf

机构地区 Electrical Engineering Department Material Sciences Department

出处《Journal of Semiconductors》 EI CAS CSCD 2014年第3期33-38,共6页 半导体学报（英文版）

关键词 traps pinch-off voltage resistance channel substrate interface traps pinch-off voltage resistance channel substrate interface

分类号 TN386 [电子电信—物理电子学] TN44 [电子电信—微电子学与固体电子学]

引文网络
相关文献

参考文献1

1R K Parida,N C Agrawala,G N Dash,A K Panda.Characteristics of a GaN-based Gunn diode for THz signal generation[J].Journal of Semiconductors,2012,33(8):37-43. 被引量：2

二级参考文献20

1Litinov V, et al. GaN based Terahertz source. Terahertz and gi- gahertz electronics and photonics II. Proc SPIE, 2010, 4111 : 116.
2Saad P, Fager C, Cao H, et al. Design of a highly efficient 2-4 GHz Octave band width GaN-HEMT power amplifier. IEEE Trans MTT, 2010, 58 (7): 1677.
3Esposto M, Chini A, Rajan S. Analytical model for power switch- ing GaN-based HEMT design. IEEE Trans Electron Devices,2011, 58 (5): 1456.
4Heller E R, Ventury R, Green D S. Development of a versatile physics-based finite-element model of an A1GaN/GaN HEMT capable of accommodating process and epitaxy variations and a librated using multiple DC parameter. IEEE Trans Electron De- vices, 2011, 58(4): 1091.
5Lenka T R, Panda A K. Role ofnanoscale A1N and InN for the mi- crowave characteristics of A1GaN/(A1, In)N/GaN-based HEMT. Semiconductors, 2011,45(5): 650.
6Panda A K, Pavlidis D, Alekseev E. DC and high-frequency characteristics ofGaN-based IMPATTs. IEEE Trans Electron De- vices, 2001, 48:820.
7Panda A K, Pavlidis D, Alekseev E. Noise characteristics of GaN-based IMPATTs. IEEE Trans Electron Devices, 2001, 48: 1473.
8Albrecht J D, Wang R P, Ruden P P, et al. Electronic transport characteristics of GaN for high temperature device modeling. J Appl Phys, 1998, 83(9): 4777.
9Yang L A, Hao Y, Yao Q, et al. Improved negative differential mobility model of GaN and A1GaN for a Terahertz Gunn diode. IEEE Trans Electron Devices, 2011, 58(4): 1076.
10Lau K S, Tozer R C, David J P R, et al. Double transit region Gunn diodes. Semicond Sci Technol, 2007, 22:245.

共引文献1

1常永明,郝跃.晶向的各向异性对InN耿氏二极管的影响[J].半导体光电,2019,40(6):781-785.

引证文献1

1戈勤,陶洪琪,余旭明.A 1.8–3 GHz-band high efficiency GaAs pHEMT power amplifier MMIC[J].Journal of Semiconductors,2015,36(12):124-127. 被引量：1

二级引证文献1

1林倩,陈思维,邬海峰,胡单辉,陈依军,胡柳林.基于GaAs pHEMT工艺的S波段高增益驱动放大器的设计研究[J].电子器件,2021,44(4):802-805. 被引量：1

1郑长鉴,贾默伊.集电结中的碰撞电离对砷化镓晶体管交流参数的影响[J].半导体技术,1996,12(2):35-36.
2张倩,孙玲玲,文进才.毫米波二倍频器的研究与设计[J].杭州电子科技大学学报（自然科学版）,2013,33(6):17-20. 被引量：6
3邢凌燕.利用ADS设计基于MESFET的宽带功率放大器[J].光通信研究,2008(6):58-61. 被引量：5
4王克亮,闫萍,郭晓丽.结型场效应晶体管的主要参数的探讨[J].山东电子,2002(2):40-41. 被引量：3
5单满春.结型场效应晶体管的主要参数的探讨[J].黑龙江科技信息,2004(9):26-26.
6平生.量子检测器[J].中国科教创新导刊,2000,0(8):23-23.
7威锋.美国研究人员研制成功新型碳纳米晶体管[J].军民两用技术与产品,2016,0(19):28-28.
8王海平,刘章文.FET/pHEMT器件寄生电阻的精确测量[J].计量技术,2016(1):33-35.
9闫云斌,全厚德,崔佩璋.GMSK跳频通信跟踪干扰性能分析[J].电子技术应用,2012,38(5):109-112. 被引量：7
10张翔,赵立坤,孙昱,周东方.行波管线性器预失真电路的研究与实现[J].信息工程大学学报,2008,9(4):415-418.

Journal of Semiconductors

2014年第3期

浏览历史

内容加载中请稍等...