Mechanisms of trapping effects in short-gate GaN-based high electron mobility transistors with pulsed I-V measurement

Zhou Xing-Ye; Lv Yuan-Jie; Tan Xin; Wang Yuan-Gang; Song Xu-Bo; He Ze-Zhao; Zhang Zhi-Rong; Liu Qing-Bin; Han Ting-Ting; Fang Yu-Long; Feng Zhi-Hong

doi:10.7498/aps.67.20180474

Abstract

Deep-level trapping effect is one of the most critical issues that restrict the performance improvement of GaN-based microwave power devices. It is of very importance for material growth and device development to study the trapping behavior in the device. In the past decades, there have been made a lot of efforts to characterize and investigate the deep-level trapping phenomena. However, most of the previous researches focused on the large-scale devices. For pursuing higher frequency, the devices need to be scaled down. Consequently, it becomes more difficult to characterize the deep-level traps in small-scale GaN-based devices, since none of the traditional characterization techniques such as capacitance-voltage (C-V) measurement and capacitance deep-level transient spectroscopy (C-DLTS) are applicable to small devices. Pulsed I-V measurement and transient simulation are useful techniques for analyzing trapping effects in AlGaN/GaN high electron mobility transitors (HEMTs). In this work, AlGaN/GaN metal-oxide-semiconductor HEMTs (MOSHEMTs) with very short gate length (Lg=80 nm) are fabricated. Based on the pulsed I-V measurement and two-dimensional transient simulation, the influence of deep-level trap on the dynamic characteristic of short-gate AlGaN/GaN MOSHEMT is investigated. First, the pulsed I-V characteristics of AlGaN/GaN MOSHEMT with different quiescent bias voltages are studied. In addition, the current collapse induced by the trapping effect is extracted as a function of the quiescent bias voltage. Furthermore, the transient current of AlGaN/GaN MOSHEMT is simulated with the calibrated model, and the simulation exhibits a similar result to the measurement. Moreover, the physical mechanism of trapping effect in the device is analyzed based on the experimental data and simulation results. It is shown that the current collapse of AlGaN/GaN MOSHEMT varies non-monotonically with the increase of the gate quiescent bias voltage, which results from the combination effect of the gate leakage injection-related and hot electron injection-related mechanism. In the off state, the current collapse is mainly induced by the traps below the gate, which is dominated by the gate leakage injection mechanism, leading to the decrease of current collapse with the increase of the gate bias voltage. In the on state, the hot electron injection mechanism becomes the dominant factor for trapping effect in the drain access region, resulting in the increase of current collapse. The results in this work indicate that the trap-induced current collapse can be further suppressed by improving the quality of gate dielectric to minimize the gate reverse leakage and by reducing the trap density in the epitaxial layer.

Keywords:

Authors and contacts

1.
National Key Laboratory of ASIC, Hebei Semiconductor Research Institute, Shijiazhuang 050051, China

Corresponding author: Lv Yuan-Jie, yuanjielv@163.com

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 61604137, 61674130).

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Cited By

[1]	Pengelly R S, Wood S M, Milligan J W, Sheppard S T, Pribble W L 2012 IEEE Trans. Microw. Theory Tech. 60 1764
[2]	Pu Y, Pang L, Chen X J, Yuan T T, Luo W J, Liu X Y 2011 Chin. Phys. B 20 097305
[3]	Zhang C, Wang M, Xie B, Wen C P, Wang J, Hao Y, Wu W, Chen K J, Shen B 2015 IEEE Trans. Electron Dev. 62 2475
[4]	Meneghesso G, Verzellesi G, Pierobon R, Rampazzo F, Chini A, Mishra U K, Canali C, Zanoni E 2004 IEEE Trans. Electron Dev. 51 1554
[5]	Tirado J M, Sanchez-Rojas J L, Izpura J I 2007 IEEE Trans. Electron Dev. 54 410
[6]	Wang M, Yan D, Zhang C, Xie B, Wen C P, Wang J, Hao Y, Wu W, Shen B 2014 IEEE Electron Dev. Lett. 35 1094
[7]	Meneghini M, Rossetto I, Bisi D, Stocco A, Chini A, Pantellini A, Lanzieri C, Nanni A, Meneghesso G, Zanoni E 2014 IEEE Trans. Electron Dev. 61 4070
[8]	Bisi D, Meneghini M, Santi C, Chini A, Dammann M, Brckner P, Mikulla M, Meneghesso G, Zanoni E 2013 IEEE Trans. Electron Dev. 60 3166
[9]	Braga N, Mickevicius R 2004 Appl. Phys. Lett. 85 4780
[10]	Chini A, Lecce V D, Esposto M, Meneghesso G, Zanoni E 2009 IEEE Electron Dev. Lett. 30 1021
[11]	Miccoli C, Martino V C, Reina S, Rinaudo S 2013 IEEE Electron Dev. Lett. 34 1121
[12]	Zhou X, Feng Z, Wang L, Wang Y, Lv Y, Dun S, Cai S 2014 Solid-State Electron. 100 15
[13]	Yu C H, Luo X D, Zhou W Z, Luo Q Z, Liu P S 2012 Acta Phys. Sin. 61 207301 (in Chinese)[余晨辉, 罗向东, 周文政, 罗庆洲, 刘培生 2012 物理学报 61 207301]
[14]	Gu J, Lu H, Wang Q 2011 Acta Phys. Sin. 60 077107 (in Chinese)[顾江, 鲁宏, 王强 2011 物理学报 60 077107]
[15]	Wang X D, Hu W D, Chen X S, Lu W 2012 IEEE Trans. Electron Dev. 59 1393
[16]	Hu W D, Chen X S, Quan Z J, Xia C S, Lu W, Ye P D 2006 J. Appl. Phys. 100 074501
[17]	Hu W D, Chen X S, Quan Z J, Xia C S, Lu W, Yuan H J 2006 Appl. Phys. Lett. 89 243501
[18]	Zhang G C, Feng S W, Zhou Z, Li J W, Guo C S 2011 Chin. Phys. B 20 027202
[19]	Zhang Y, Feng S, Zhu H, Zhang J, Deng B 2013 Microelectron. Reliab. 53 694
[20]	Kim S, Nah J, Jo I, Shahrjerdi D, Colombo L, Yao Z, Tutuc E, Banerjee S K 2009 Appl. Phys. Lett. 94 062107
[21]	Badmaev A, Che Y C, Li Z, Wang C, Zhou C W 2012 ACS Nano 6 3371
[22]	Tan X, Zhou X Y, Guo H Y, Gu G D, Wang Y G, Song X B, Yin J Y, L Y J, Feng Z H 2016 Chin. Phys. Lett. 33 098501

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Vol. 67, Issue 17 - 2018-09-05

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