高跨导AlGaN/GaN HEMT器件

报道了生长在蓝宝石衬底上的AlGaN/GaN HEMT器件的制造工艺以及在室温下器件的性能.器件的栅长为1.0μm,源漏间距为4.0μm.器件的最大电流密度达到1000mA/mm,最大跨导高达198mS/mm,转移特性曲线表现出增益带宽较宽的特点.同时由所测得的S参数推出栅长为1.0μm器件的截止频率(fT)和最高振荡频率(fmax)分别为18.7GHz和19.1GHz.     

Improved InAlAs/InGaAs HEMT characteristics by inserting an InAslayer into the InGaAs channel

An InAlAs/InGaAs HEMT with a thin InAs layer inserted into the InGaAs channel is proposed and its electron transport properties and device performances have been investigated. By optimizing the thickness and the exact point of insertion in the InAs layer, the mobility and electron velocity at 300 K have been increased by 30% and 15%, respectively, compared to the conventional heterostructure. In addition, a maximum intrinsic transconductance of 970 mS/mm and a maximum current gain cutoff frequency of 58.1 GHz have been attained by a 0.6 μm-gate-length device     

Performance assessment and sub-threshold analysis of gate material engineered AlGaN/GaN HEMT for enhanced carrier transport efficiency

The present work explores the features of gate material engineered (GME) AlGaN/GaN high electron mobility transistor (HEMT) for enhanced carrier transport efficiency (CTE) and suppressed short channel effects (SCEs) using 2-D sub-threshold analysis and device simulation. The model accurately predicts the channel potential, electric field and sub-threshold current for the conventional and GME HEMT, taking into account the effect of work function difference of the two metal gates. This is verified by comparing the model results with the ATLAS simulation results. Further, simulation study has been extended to reflect the wide range of benefits exhibited by GME HEMT for its on-state and analog performance. The simulation results demonstrate that the GME HEMT exhibits much higher on current, lower conductance and higher transconductance as compared to the conventional HEMT due to improved CTE and reduced SCEs. This in turn has a direct bearing on the device figure of merits (FOMs) such as intrinsic gain, device efficiency and early voltage. Tuning of GME HEMT in terms of the relative lengths of the two metal gates, their work function difference and barrier layer thickness has further been carried out to enhance the drive current, transconductance and the device FOMs illustrating the superior performance of GME HEMT for future high-performance high-speed switching, digital and analog applications.     

不同AlGaN层厚度的AlGaN/GaN高电子迁移率晶体管的静态特性

利用金属有机化合物气相外延技术研究了AlGaN/GaN高电子迁移率晶体管(HEMT)结构的外延生长及器件制作,重点比较了具有不同AlGaN层厚度的HEMT器件的静态特性.实验发现具有较薄AlGaN隔离层的结构表现出较好的器件特性.栅长为1μm的器件获得了650mA/mm的最大饱和电流密度和100mS/mm的最大跨导.     

蓝宝石衬底上槽栅型X波段增强型AlGaN/GaN HEMT

研制了一款X波段增强型AlGaN/GaN高电子迁移率晶体管(HEMT)。在3英寸(1英寸=2.54 cm)蓝宝石衬底上采用低损伤栅凹槽刻蚀技术制备了栅长为0.3μm的增强型AlGaN/GaN HEMT。所制备的增强型器件的阈值电压为0.42 V,最大跨导为401 mS/mm,导通电阻为2.7Ω·mm。器件的电流增益截止频率和最高振荡频率分别为36.1和65.2 GHz。在10 GHz下进行微波测试,增强型AlGaN/GaN HEMT的最大输出功率密度达到5.76 W/mm,最大功率附加效率为49.1%。在同一材料上制备的耗尽型器件最大输出功率密度和最大功率附加效率分别为6.16 W/mm和50.2%。增强型器件的射频特性可与在同一晶圆上制备的耗尽型器件相比拟。     

Integration of GalnP/GaAs heterojunction bipolar transistors andhigh electron mobility transistors

Integration of carbon-doped GaInP/GaAs heterojunction bipolar transistors (HBTs) and high electron mobility transistors (HEMTs) is demonstrated by growing an HBT on the top of a HEMT. A current gain of 60, a cutoff frequency of 59 GHz and a maximum oscillation frequency of 68 GHz were obtained for a 5×15 μm² self-aligned HBT. The HEMT, with a gate length of 1.5 μm has a transconductance of 210 mS/mm, a cutoff frequency of 9 GHz and a maximum oscillation frequency of 22 GHz. It is shown that the GaInP/GaAs HBT on the HEMT is a simple Bi-FET technology suitable for microwave and mixed signal applications     

X波段大功率GaN HEMT的研制

在研制了AlGaN/GaN HEMT外延材料的基础上,采用标准工艺制作了2.5mm大栅宽AlGaN/GaNHEMT。直流测试中,Vg=0V时器件的最大饱和电流Ids可达2.4A,最大本征跨导Gmax为520mS,夹断电压Voff为-5V;通过采用带有绝缘层的材料结构及离子注入的隔离方式,减小了器件漏电,提高了击穿电压,栅源反向电压到-20V时,栅源漏电在10-6A数量级;单胞器件测试中,Vds=34V时,器件在8GHz下连续波输出功率为16W,功率增益为6.08dB,峰值功率附加效率为43.0%;2.5mm×4四胞器件,在8GHz下,连续波输出功率42W,功率增益8dB,峰值功率附加效率34%。     

InP基RTD/HEMT集成的几个关键工艺研究

用MBE设备在半绝缘的InP衬底上依次生长高电子迁移率晶体管(HEMT)外延材料和共振遂穿二极管(RTD)外延材料,在此材料结构基础上研究和分析了RTD与HEMT器件单片集成工艺中的隔离工艺、欧姆接触工艺、HEMT栅挖槽工艺和空气桥工艺等几步关键工艺,给出了这些工艺的相关参数。利用上述工艺成功地制作了RTD和HEMT器件,并在室温下分别测试了RTD器件和HEMT器件的电学特性。测试表明:在室温下,RTD器件的峰电流密度与谷电流密度之比(PVCR)为3.66;HEMT器件的最大跨导约为370 mS/mm,在Vds=1.5 V时的饱和电流约为391 mA/mm。这将为RTD与HEMT的单片集成研究奠定工艺基础。     

Temperature-dependent investigation of a high-breakdown voltage andlow-leakage currentGa0.51In0.49P/In0.15Ga0.85Aspseudomorphic HEMT

We reported a newly designed double delta-doped GaInP/InGaAs pseudomorphic HEMT with high temperature-dependent performances. In addition to the novel aspects of the proposed HEMT structure, temperature-dependent behaviors including a high-voltage (40 V) and a low-leakage current (17 nA/mm) are further improved by eliminating mesa-sidewall effect. We obtained nearly current-independent transconductance in the temperature of 300-450 K. The measured current gain cutoff frequency f_T and maximum oscillation frequency f _max for a 1-μm gate device are 12 and 28.4 GHz, respectively     

功率PHEMT的直流特性研究

描述了高电子迁移率晶体管的作用、工作原理及发展概况，叙述了器件特性。制作出了栅长为１μｍ的ＰＨＥＭＴ样品，它的最大跨导为１７０ｍＳ／ｍｍ，击穿电压为４Ｖ，最大电流密度为２７０ｍＡ／ｍｍ，阈值电压为１．５Ｖ。     

AlGaN/GaN HEMT器件的研制

介绍了AlGaN/GaNHEMT器件的研制及室温下器件特性的测试.漏源欧姆接触采用Ti/Al/Pt/Au ,肖特基结金属为Pt/Au .器件栅长为1μm ,获得的最大跨导为12 0mS/mm ,最大的漏源饱和电流密度为0 95A/mm .     

AlGaN/GaN HEMTs With Thin InGaN Cap Layer for Normally Off Operation

AlGaN/GaN HEMTs with a thin InGaN cap layer have been proposed to implement the normally off HEMTs. The key idea is to employ the polarization-induced field in the InGaN cap layer, by which the conduction band is raised, which leads to the normally off operation. The fabricated HEMT with an In_0.2Ga_0.8N cap layer with a thickness of 5 nm showed normally off operation with a threshold voltage of 0.4 V and a maximum transconductance of 85 mS/mm for the device with a 1.9-mum-long gate. By etching off the In_0.2Ga_0.8N cap layer at the access region using gate electrode as an etching mask, the maximum transconductance has increased from 85 to 130 mS/mm due to a reduction of the parasitic source resistance.     

InP基InAlAs-InAs HEMT

对ＩｎＡｓ沟道ＩｎＡｌＡｓ－ＩｎＡｓ高电子迁移率晶体管材料及器件的设计和器件制作工艺进行了研究，器件样品性能良好，１μｍ栅长ＩｎＡｌＡｓ－ＩｎＡｓＨＥＭＴ器件的最大跨导３００Ｋ时达到２５０ｍＳ／ｍｍ。这是国内首次研制成功的ＩｎＡｓ沟道ＨＥＭＴ器件。     

High-performance enhancement-mode AlGaN/GaN HEMTs using fluoride-based plasma treatment

We report a novel approach in fabricating high-performance enhancement mode (E-mode) AlGaN/GaN HEMTs. The fabrication technique is based on fluoride-based plasma treatment of the gate region in AlGaN/GaN HEMTs and post-gate rapid thermal annealing with an annealing temperature lower than 500/spl deg/C. Starting with a conventional depletion-mode HEMT sample, we found that fluoride-based plasma treatment can effectively shift the threshold voltage from -4.0 to 0.9 V. Most importantly, a zero transconductance (g/sub m/) was obtained at V/sub gs/=0 V, demonstrating for the first time true E-mode operation in an AlGaN/GaN HEMT. At V/sub gs/=0 V, the off-state drain leakage current is 28 /spl mu/A/mm at a drain-source bias of 6 V. The fabricated E-mode AlGaN/GaN HEMTs with 1 /spl mu/m-long gate exhibit a maximum drain current density of 310 mA/mm, a peak g/sub m/ of 148 mS/mm, a current gain cutoff frequency f/sub T/ of 10.1 GHz and a maximum oscillation frequency f/sub max/ of 34.3 GHz.     

最大振荡频率为200GHz的蓝宝石衬底AlGaN/GaN HEMT

报道了最大振荡频率为200 GHz的基于蓝宝石衬底的AlGaN/GaN高电子迁移率晶体管(HEMT).外延材料结构采用InGaN背势垒层来减小短沟道效应,器件采用凹栅槽和T型栅结合的工艺,实现了Ka波段AlGaN/GaNHEMT.器件饱和电流达到1.1 A/mm,跨导为421 mS/mm,截止频率(fT)为30 GHz...     

应用一种新T形栅版图设计方法的AlGaN/GaN高电子迁移率晶体管

在蓝宝石衬底上制作AlGaN/GaN高电子迁移率品体管.由于使用了一种全新的T形栅电子束曝光版图,因此可以自由地改变T形栅的宽窄比(T形栅头部尺寸与栅长的比值)并优化T形栅的形状.所得的0.18μm栅长的器件,其特征频率(fT)为65GHz,T形栅的宽窄比为10.同时,测得的峰值跨导为287mS/mm,最大电流街度为980mA/mm.     

OEIC光接收机研究的湿法选择腐蚀

试验了用柠檬酸与双氧水系列腐蚀液来实现ＩｎＡｌ（Ｇａ）Ａｓ∶ＩｎＰ和ＩｎＧａＡｓ∶ＩｎＡｌＡｓ的选择腐蚀,达到了较好的效果,且工艺重复性好。同一单片上ＭＳＭ（金属－半导体－金属）光探测器的光响应度可达到０．５Ａ／Ｗ,ＨＥＭＴ器件最大跨导为３０５ｍＳ／ｍｍ,最大饱和电流密度为３５０ｍＡ／ｍｍ。完成了实现ＯＥＩＣ光接收机的关键一步。     

RF and microwave characteristics of a 10 nm thick InGaN-channel gate recessed HEMT

A new depletion-mode gate recessed AlGaN/InGaN/GaN-high electron mobility transistor(HEMT)with 10 nm thickness of InGaN-channel is proposed.A growth of AlGaN over GaN leads to the formation of twodimensional electron gas(2DEG)at the heterointerface.High 2DEG density(ns)is achieved at the heterointerface due to a strain induced piezoelectric effect between AlGaN and GaN layers.The electrons are confined in the InGaN-channel without spilling over into the buffer layer,which also reduces the buffer leakage current.From the input transfer characteristics the threshold voltage is obtained as 4:5 V and the device conducts a current of 2 A/mm at a drain voltage of 10 V.The device also shows a maximum output current density of 1.8 A/mm at Vds of 3 V.The microwave characteristics like transconductance,cut-off frequency,max frequency of oscillation and Mason’s Unilateral Gain of the device are studied by AC small-signal analysis using a two-port network.The stability and power performance of the device are analyzed by the Smith chart and polar plots respectively.To our knowledge this proposed InGaN-channel HEMT structure is the first of its kind.     

AlGaN-GaN HEMTs on patterned silicon (111) substrate

We report the AlGaN-GaN high-electron mobility transistors (HEMTs) grown and fabricated on patterned silicon (111) substrates. A crack-free AlGaN-GaN HEMT heterostructure was grown on top of rectangular silicon ridges patterned on the silicon substrate. Fabrication of HEMT on the ridges was demonstrated using a polyimide planarization process. Maximum drain current density of 1.05 A/mm and peak transconductance of 150 mS/mm were achieved with 1.0 /spl mu/m gate-length. The current gain cutoff frequency and maximum frequency of oscillation were 9.7 and 20.5 GHz, respectively, for the 1 /spl mu/m /spl times/ 300 /spl mu/m devices.     

Enhancement-mode pseudomorphic inverted HEMT for low noiseamplifier

Characteristics of the pseudomorphic inverted HEMT (P-I-HEMT) are compared with those of the pseudomorphic HEMT. Both devices were fabricated in enhancement mode by the same process. P-I-HEMT shows a higher maximum transconductance of 590 mS/mm, and higher K-value of 600 mS/Vmm at a threshold voltage of O V, and better pinch-off characteristics than its counterpart. Noise characteristics of P-I-HEMT are reported. Lower noise figure (1.0 dB at 18 GHz) was obtained in the P-I-HEMT. It is concluded that the P-I-HEMT shows far better noise characteristics than the other at low drain voltage and current