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In order to improve the radiation-resistance ability of the InP based high electron mobility transistor (InP HEMT) by optimizing the epitaxial structure design, a series of InP HEMT epitaxial structure materials with different structure parameters is grown by gas source molecular beam epitaxy. These samples are irradiated at room temperature by a 1.5-MeV electron beam at the same irradiation fluence of 2 × 1015 cm–2. The electrical properties of the two-dimensional electron gas (2DEG) for InP HEMT epitaxial materials before and after irradiation are measured by Hall measurements to obtain the changes of the normalized 2DEG density and electron mobility along with the epitaxial structure parameters. The relation between 2DEG radiation damage and epitaxial structure parameters (such as Si-δ-doping density, spacer thickness, channel thickness and channel In content) of InP HEMT epitaxial structure materials is analyzed. The results show that the 2DEG of the InP HEMT epitaxial structure material with higher Si-δ-doping density, thinner spacer thickness, thicker channel thickness and lower channel In content has lower radiation damage, which possesses the stronger radiation-resistance ability.
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Keywords:
- InP based high electron mobility transistor /
- two-dimensional electron gas /
- electron beam irradiation /
- radiation-resistance
[1] Cha E, Wadefalk N, Moschetti G, Pourkabirian A, Stenarson J, Grahn J 2020 IEEE Electron Device Lett. 41 1005
Google Scholar
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Google Scholar
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Lin L B, Li Y M, Chen W D, Jiang J J, Kong M Y 1995 J. Sichuan Univ. (Nat. Sci. Ed.) 32 39
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图 1 V90型气态源分子束外延生长系统
Figure 1. V90 gas source molecular beam epitaxy growth system.
图 2 InP HEMT结构材料TEM分析图
Figure 2. TEM analysis diagram of InP HEMT structural material.
图 3 电子辐照对不同δ掺杂浓度InP HEMT二维电子气浓度和电子迁移率的归一化影响 (a)室温; (b) 77 K
Figure 3. Normalized 2DEG density (n) and electron mobility (u) versus δ-doping density measured at (a) room-temperature and (b) 77 K irradiated by electron beam.
图 4 电子辐照对不同隔离层厚度InP HEMT二维电子气浓度和电子迁移率的归一化影响 (a)室温; (b) 77 K
Figure 4. Normalized 2DEG density (n) and electron mobility (u) versus spacer layer thickness measured at (a) room-temperature and (b) 77 K irradiated by electron beam.
图 5 电子辐照对不同InGaAs沟道In组分InP HEMT二维电子气浓度和电子迁移率的归一化影响 (a)室温; (b) 77 K
Figure 5. Normalized 2DEG density (n) and electron mobility (u) versus channel In content measured at (a) room-temperature and (b) 77 K irradiated by electron beam.
图 6 电子辐照对不同沟道厚度InP HEMT二维电子气浓度和电子迁移率的归一化影响 (a)室温; (b) 77 K
Figure 6. Normalized 2DEG density (n) and electron mobility (u) versus channel thickness measured at (a) room-temperature and (b) 77 K irradiated by electron beam.
图 7 InGaAs/InAlAs应变异质结的外延生长及弛豫示意图 (a)两种不同晶格常数外延层; (b)应变异质结; (c)弛豫异质结
Figure 7. Schematic diagram of epitaxial growth and relaxation of InGaAs/InAlAs strained heterojunction: (a) Epitaxial layers with different lattice constants; (b) strained heterojunction; (c) relaxation heterojunction.
表 1 InP HEMT外延结构表(S.I.InP sub, 半绝缘InP衬底)
Table 1. Structure parameters of the InP HEMT (S.I.InP sub, semi-insulating InP substrate)
Layer Material Doping Thickness/nm Cap layer 1 In0.65Ga0.35As n+ 10 Cap layer 2 In0.53Ga0.47As n+ 15 Cap layer 3 In0.52Al0.48As n+ 15 Etch-stopper InP un 4 Barrier layer In0.52Al0.48As un 8 δ-doping Si (3—6)×1012 cm–2 Spacer layer In0.52Al0.48As un hw Channel InxGa1–xAs un tw Buffer layer In0.52Al0.48As un 300 S.I.InP sub 
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表 2 InP HEMT外延结构样品辐照前霍尔测试数据
Table 2. Hall data of the InP HEMT structures before irradiation
Sample
No.RT 77 K n/
(1012 cm–2)u/
(cm2·V–1·s–1)n/
(1012 cm–2)u/
(cm2·V–1·s–1)A1 1.851 8010 1.858 17100 A2 2.201 7920 2.205 16500 A3 2.394 7810 2.402 15900 A4 2.695 7530 2.700 14800 B1 2.557 7870 2.557 15100 B2 2.394 7810 2.402 15900 B3 2.272 7980 2.270 16700 B4 2.105 8110 2.085 17600 C1 2.408 8310 2.410 18400 C2 2.420 8960 2.421 22600 C3 2.431 9510 2.430 26200 C4 2.444 10500 2.445 32100 D1 2.387 7780 2.357 15600 D2 2.394 7810 2.402 15900 D3 2.398 7820 2.404 16000 D4 2.340 7810 2.405 16100
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[1] Cha E, Wadefalk N, Moschetti G, Pourkabirian A, Stenarson J, Grahn J 2020 IEEE Electron Device Lett. 41 1005
Google Scholar
[2] Hamada H, Tsutsumi T, Matsuzaki H, Fujimura T, Abdo I, Shirane A, Okada K, Itami G, Song H J, Sugiyama H, Nosaka H 2020 IEEE J. Solid-State Circuits 55 2316
Google Scholar
[3] Sato M, Niida Y, Suzuki T, Nakasha Y, Kawano Y, Iwai T, Hara N, Joshin K 2017 IEICE Trans. Electron. E100C 417
Google Scholar
[4] Tang J J, Liu G P, Zhao G J, Xing S, Malik S A 2020 J. Vac. Sci. Technol. B 38 023202
Google Scholar
[5] Tang J J, Liu G P, Song J Y, Zhao G J, Yang J H 2021 Chin. Phys. B 30 027303
Google Scholar
[6] 谷文萍, 张进城, 王冲, 冯倩, 马晓华, 郝跃 2009 58 1161
Google Scholar
Gu W, Zhang J C, Wang C, Feng Q, Ma X H, Hao Y 2009 Acta Phys. Sin. 58 1161
Google Scholar
[7] Ives N E, Chen J, Witulski A F, Schrimpf R D, Fleetwood D M, Bruce R W, McCurdy M W, Zhang E X, Massengill L W 2015 IEEE Trans. Nucl. Sci. 62 2417
Google Scholar
[8] Fleetwood D M 2015 IEEE Trans. Nucl. Sci. 62 1462
Google Scholar
[9] Sun S X, Ding P, Jin Z, Zhong Y H, Li Y X, Wei Z C 2019 Nanomaterials 9 967
Google Scholar
[10] Daoudi M, Kaouach H, Hosni F 2016 Optik 127 7188
Google Scholar
[11] 陈睿, 梁亚楠, 韩建伟, 王璇, 杨涵, 陈钱, 袁润杰, 马英起, 上官士鹏 2021 70 116102
Google Scholar
Chen R, Liang Y N, Han J W, Wang X, Yang H, Chen Q, Yuan R J, Ma Y Q, Shangguan S P 2021 Acta Phys. Sin. 70 116102
Google Scholar
[12] Sun S X, Yang B, Zhong Y H, Li Y X, Ding P, Jin Z, Wei Z C 2020 J. Phys. D: Appl. Phys. 53 175107
Google Scholar
[13] Warner J H, McMorrow D, Buchner S, Boos J B, Roche N, Paillet P, Gaillardin M, Blackmore E, Trinczek M, Ramachandran V, Reed R A, Schrimpf R D 2013 IEEE Trans. Nucl. Sci. 60 2651
Google Scholar
[14] Pearton S J, Ren F, Patrick E, Law M E, Polyakov A Y 2016 ECS J. Solid State Sci. Technol. 5 Q35
Google Scholar
[15] Lin L B, Liao Z, Liu Q, Lu T, Feng X 2002 Surf. Coat. Technol. 158 737
Google Scholar
[16] 林理彬, 李有梅, 陈卫东, 蒋锦江, 孔梅影 1995 四川大学学报 (自然科学版) 32 39
Lin L B, Li Y M, Chen W D, Jiang J J, Kong M Y 1995 J. Sichuan Univ. (Nat. Sci. Ed.) 32 39
[17] Tang J J, Liu G P, Mao B Y, Ali S, Zhao G J, Yang J H 2021 Phys. Lett. A 410 127527
Google Scholar
[18] Zhang Z, Cardwell D, Sasikumar A, Kyle E C H, Chen J, Zhang E X, Fleetwood D M, Schrimpf R D, Speck J S, Arehart A R, Ringel S A 2016 J. Appl. Phys. 119 165704
Google Scholar
[19] Smith M D, O'Mahony D, Vitobello F, Muschitiello M, Costantino A, Barnes A R, Parbrook P J 2016 Semicond. Sci. Technol. 31 025008
Google Scholar
[20] Zhong Y H, Yang B, Chang M M, Ding P, Ma L H, Li M K, Duan Z Y, Yang J, Jin Z, Wei Z C 2020 Chin. Phys. B 29 038502
Google Scholar
[21] Zhou S X, Qi M, Ai L K, Xu A H, Wang L D, Ding P, Jin Z 2015 Chin. Phys. Lett. 32 097101
Google Scholar
[22] Klaassen D B M 1992 Solid-State Electron. 35 961
Google Scholar
[23] 玛丽娅, 李豫东, 郭旗, 艾尔肯, 王海娇, 汪波, 曾骏哲 2015 64 154217
Google Scholar
Ma L Y, Li Y D, Guo Q, Ai E, Wang H J, Zeng J 2015 Acta Phys. Sin. 64 154217
Google Scholar
[24] Anderson N G, Laidig W D, Kolbas R M, Lo Y C 1986 J. Appl. Phys. 60 2361
Google Scholar
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