Composite channel 100 nm InP HEMT with ultrathin barrier for millimetre wave applications

毫米波 高电子迁移率晶体管 光电子学 复合数 材料科学 频道(广播) 电气工程 复合材料 晶体管 工程类 电压
作者
S. Nandi,Shashank Kumar Dubey,Mukesh Kumar,Aminul Islam
出处
期刊:Engineering research express [IOP Publishing]
卷期号:6 (1): 015316-015316
标识
DOI:10.1088/2631-8695/ad2efa
摘要

Abstract This study introduces a High Electron Mobility Transistor (HEMT) designed for millimeter-wave applications, utilizing a composite channel structure based on InP and InGaAs-InAs-InGaAs. The proposed device incorporates an ultra-thin 2 nm barsrier layer, a distinctive composite channel topology, and a judicious selection of III-V materials. These features collectively contribute to an improved confinement of electrons within the channel, thereby improving the concentration of two-dimensional electron gas (2DEG), and consequently, enhancing the mobility and speed of the device. The proposed device exhibits a unity current gain frequency ( f T ) of 249 GHz and a maximum oscillation frequency ( f MAX ) of 523.9 GHz, accompanied by a current gain of 67.7 dB at 0.1 GHz. The off-state leakage current is maintained within the nanoampere range, and the minimum noise figure ( NF MIN ) is merely 0.76 dB at 10 GHz. A comparative analysis of DC and RF performance, along with an examination of associated parasitic elements, is conducted among various composite channel HEMTs proposed in recent literature. A quantitative justification is provided for the superiority of InGaAs-InAs-InGaAs channel HEMTs, establishing their heightened f T and f MAX . The proposed InGaAs-InAs-InGaAs channel HEMTs exhibit 1.4 times improved f T and f MAX , coupled with only half the NF MIN in comparison to their InGaAs-InP-InGaAs channel counterparts. To further comprehend the device’s behavior under varying RF conditions, a frequency-dependent intrinsic Field-Effect Transistor (FET) model is presented. This model facilitates the analysis of the device’s performance and allows the identification of the impact of individual parameters on the overall system.
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