AlN/β-Ga2O3HEMT直流特性仿真

摘要/Abstract

摘要： 本文利用器件仿真软件对AlN/β-Ga₂O₃高电子迁移率晶体管(HEMT)器件的直流特性进行研究。由于AlN具有很强的极化效应,在AlN/β-Ga₂O₃异质结界面处产生高浓度二维电子气(2DEG),使AlN/β-Ga₂O₃异质结基HEMT具有更加优越的器件性能。理论计算得到AlN/β-Ga₂O₃异质结界面处产生的面电荷密度为2.75×10¹³ cm^-2。通过分析器件的能带结构、沟道电子浓度分布,研究AlN势垒层厚度、栅极长度、栅漏间距,以及金属功函数等参数对器件转移特性和输出特性的影响。结果表明:随着AlN势垒层厚度的增大,阈值电压减小,最大跨导减小,沟道电子浓度增大使饱和漏电流增大;随着栅极长度缩短,跨导增大,当栅极长度缩短至0.1 μm时,器件出现了短沟道效应,并且随着栅极长度的缩短,栅下沟道区电子浓度增大,而电子速度基本不变,导致饱和漏电流增大,导通电阻减小,并且器件的饱和特性变差;随着栅漏间距的增大,跨导增大,沟道区电子浓度不变,而电子速度略有增加,导致饱和漏电流增大;肖特基栅金属功函数的增加会增大阈值电压,不会改变器件跨导,沟道电子浓度减小导致饱和漏电流减小。上述结论为后面的器件的优化改进提供了理论依据。

关键词: β-Ga₂O₃, AlN, HEMT, 阈值电压, 跨导, 饱和漏电流

Abstract: DC characteristics of AlN/β-Ga₂O₃ high-electron-mobility-transistor (HEMT) was studied in this paper by using the device simulation software. Due to the strong polarization effect of AlN, a high concentration of two-dimensional electron gas (2DEG) is generated at the interface of AlN/β-Ga₂O₃ heterojunction, resulting in AlN/β-Ga₂O₃ heterojunction based HEMT exhibits superior device performance. Theoretical calculation shows that the surface charge density generated at the interface of AlN/β-Ga₂O₃ heterojunction is 2.75×10¹³ cm^-2. By analyzing the energy band structure and channel electron concentration distribution of the device, the effects of parameters such as AlN barrier layer thickness, gate length, gate drain spacing, and metal work function on the transfer and output characteristics of the device were studied. The following results were obtained. As the thickness of AlN barrier layer increases, the threshold voltage decreases, the maximum transconductance decreases, and the drain saturation current increases with the increase of channel electron concentration. As the gate length shortens, the transconductance increases, and the gate length shortens to 0.1 μm, the device experienced a short channel effect. And as the gate length decreases, the electron concentration in the channel area under the gate increases, while the electron velocity remains basically unchanged, resulting in an increase in drain saturation current, a decrease in conduction resistance, and a deterioration in the saturation characteristics of the device. As the distance between the gate and drain increases, the transconductance increases, and the electron concentration in the channel region remains unchanged, while the electron velocity slightly increases, resulting in an increase in saturated leakage current. An increase in the Schottky gate metal work function will increase the threshold voltage without changing the device transconductance. The decrease in channel electron concentration will lead to a decrease in drain saturation current. The above conclusions provide a theoretical basis for the optimization and improvement of subsequent devices.

Key words: β-Ga₂O₃, AlN, HEMT, threshold voltage, transconductance, drain saturation current

中图分类号:

贺小敏, 唐佩正, 张宏伟, 张昭, 胡继超, 李群, 蒲红斌. AlN/β-Ga₂O₃HEMT直流特性仿真[J]. 人工晶体学报, 2024, 53(5): 766-772.

HE Xiaomin, TANG Peizheng, ZHANG Hongwei, ZHANG Zhao, HU Jichao, LI Qun, PU Hongbin. Simulation on DC Characteristics of AlN/β-Ga₂O₃ HEMT[J]. Journal of Synthetic Crystals, 2024, 53(5): 766-772.

参考文献

[1] JANOWITZ C, SCHERER V, MOHAMED M, et al. Experimental electronic structure of In₂O₃ and Ga₂O₃[J]. New Journal of Physics, 2011, 13(8): 085014.
[2] HIGASHIWAKI M, SASAKI K, KURAMATA A, et al. Gallium oxide (Ga₂O₃) metal-semiconductor field-effect transistors on single-crystal β-Ga₂O₃ (010) substrates[J]. Applied Physics Letters, 2012, 100(1): 013504.
[3] GHOSH K, SINGISETTI U. Ab initio velocity-field curves in monoclinic β-Ga₂O₃[J]. Journal of Applied Physics, 2017, 122(3): 035702.
[4] MA N, TANEN N, VERMA A, et al. Intrinsic electron mobility limits in beta-Ga₂O₃[J]. Appl Phys Lett, 2016, 109(21): 212101.
[5] WU C, WU F M, HU H Z, et al. Review of self-powered solar-blind photodetectors based on Ga₂O₃[J]. Materials Today Physics, 2022, 28: 100883.
[6] CHENG Y X, YE J H, LAI L, et al. Ambipolarity regulation of deep-UV photocurrent by controlling crystalline phases in Ga₂O₃ nanostructure for switchable logic applications[J]. Advanced Electronic Materials, 2023, 9(4): 2201216.
[7] CHANG M M, GUO D Y, ZHONG X L, et al. Impact of 100 MeV high-energy proton irradiation on β-Ga₂O₃ solar-blind photodetector: oxygen vacancies formation and resistance switching effect[J]. Journal of Applied Physics, 2022, 132(12): 123105.
[8] ARDARAVIČIUS L, MATULIONIS A, LIBERIS J, et al. Electron drift velocity in AlGaN/GaN channel at high electric fields[J]. Applied Physics Letters, 2003, 83(19): 4038-4040.
[9] AHMADI E, KOKSALDI O S, ZHENG X, et al. Demonstration of β-(Al_xGa_1-x)₂O₃/β-Ga₂O₃ modulation doped field-effect transistors with Ge as dopant grown via plasma-assisted molecular beam epitaxy[J]. Applied Physics Express, 2017, 10(7): 071101.
[10] ZHANG Y W, NEAL A, XIA Z B, et al. Demonstration of high mobility and quantum transport in modulation-doped β-(Al_xGa_1-x)₂O₃/Ga₂O₃ heterostructures[J]. Applied Physics Letters, 2018, 112(17): 173502-173502-5.
[11] JOISHI C, XIA Z B, MCGLONE J, et al. Effect of buffer iron doping on delta-doped β-Ga₂O₃ metal semiconductor field effect transistors[J]. Applied Physics Letters, 2018, 113(12): 123501.
[12] ZHANG Y W, JOISHI C, XIA Z B, et al. Demonstration of β-(Al_xGa_1-x)₂O₃/Ga₂O₃ double heterostructure field effect transistors[J]. Applied Physics Letters, 2018, 112(23): 233503.
[13] ZHANG Y W, ALEMA F, MAUZE A, et al. MOCVD grown epitaxial β-Ga₂O₃ thin film with an electron mobility of 176 cm²/(V s) at room temperature[J]. APL Materials, 2019, 7(2): 022506.
[14] SUN H D, TORRES CASTANEDO C G, LIU K K, et al. Valence and conduction band offsets of β-Ga₂O₃/AlN heterojunction[J]. Applied Physics Letters, 2017, 111(16): 162105.
[15] OSHIMA T, KATO Y, KAWANO N, et al. Carrier confinement observed at modulation-doped β-(Al_xGa_1-x)₂O₃/Ga₂O₃ heterojunction interface[J]. Applied Physics Express, 2017, 10(3): 035701.
[16] SINGH R, LENKA T R, VELPULA R T, et al. A novel β-Ga₂O₃ HEMT with f_T of 166 GHz and X-band P_OUT of 2.91 W/mm[J]. International Journal of Numerical Modelling: Electronic Networks, Devices and Fields, 2021, 34(1): 2794.1-2794.11.
[17] SINGH R, LENKA T R, NGUYEN H P T. Optimization of dynamic source resistance in a β-Ga₂O₃ HEMT and its effect on electrical characteristics[J]. Journal of Electronic Materials, 2020, 49(9): 5266-5271.
[18] SINGH R, LENKA T R, VELPULA R T, et al. Investigation of current collapse and recovery time due to deep level defect traps in β-Ga₂O₃ HEMT[J]. Journal of Semiconductors, 2020, 41(10): 102802.
[19] SINGH R, LENKA T R, NGUYEN H P T. 3D simulation study of laterally gated AlN/β-Ga₂O₃ HEMT technology for RF and high-power nanoelectronics[M]//LENKA TR, NGUYEN HPT. HEMT Technology and Applications. Singapore: Springer, 2023: 93-103.
[20] SINGH R, LENKA T R, NGUYEN H. T-Gate shaped AlN/β-Ga₂O₃ HEMTfor RFand high power nano electronics[EB/OL]. TechRxiv. Preprint.https://doi.org/10.36227/techrxiv.15023094.v12021-07-20/2021-12-25.
[21] SINGH R, RAO G P, LENKA T R, et al. Design and simulation of T-gate AlN/β-Ga₂O₃ HEMT for DC, RF and high-power nanoelectronics switching applications[J]. International Journal of Numerical Modelling: Electronic Networks, Devices and Fields, 2024, 37(1): e3146.
[22] INGEBRIGTSEN M E, VARLEY J B, KUZNETSOV A Y, et al. Iron and intrinsic deep level states in Ga₂O₃[J]. Applied Physics Letters, 2018, 112(4): 042104.
[23] AMBACHER O, SMART J, SHEALY J R, et al. Two-dimensional electron gases induced by spontaneous and piezoelectric polarization charges in N- and Ga-face AlGaN/GaN heterostructures[J]. Journal of Applied Physics, 1999, 85(6): 3222-3233.
[24] ZHOU Z H, LI Q, HE X M. Electron transport mechanism in AlN/β-Ga₂O₃ heterostructures[J]. Acta Physica Sinica, 2023, 72(2): 028501.

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AlN/β-Ga₂O₃HEMT直流特性仿真

Simulation on DC Characteristics of AlN/β-Ga₂O₃ HEMT

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