Seung Heon Shin , Hyeon-Seok Jeong , Yong-Hyun Kim , Yong-Soo Jeon , Ji-Min Beak , Wan-Soo Park , In-Geun Lee , Jacob Yun , Ted Kim , Jae-Hak Lee , Hyuk-Min Kwon , Dae-Hyun Kim
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引用次数: 0
Abstract
In this paper, InP Double-Heterojunction Bipolar Transistors (DHBTs) on a 3-inch InP substrate is demonstrated through stepper-based photolithography. The performance of the fabricated InP DHBTs such as DC characteristics, high-frequency characteristics, and uniformity of the 3-inch wafer is investigated to verify the stepper-based fabrication process. To improve the high-frequency characteristics, the self-aligned base-emitter contact is realized by using the high height-to-width ratio and vertical sidewall emitter profile of the Au electroplating process. The fabricated DHBTs with WE = 0.6 μm and LE = 15 μm exhibits current gain (β) = 50 at VCE = 1.0 V and an open-base common-emitter breakdown voltage (BVCEO) of 5.7 V at JC = 0.01 mA/µm2 and 7.5 V at JC = 0.1 mA/µm2, respectively. Moreover, the fabricated DHBTs with WE = 0.6 μm and LE = 15 μm show excellent fT of 244 GHz and fmax of 221 GHz at JC = 4.4 mA/μm2 and VCE = 1.6 V. In order to evaluate the uniformity of the fabricated DHBTs, we measure current gain (β) and high-frequency characteristics with WE = 0.6 μm and LE = 15 μm and the average values and standard deviation of the β, fT, and fmax are β = 49.3 ± 1.9, fT = 241.4 ± 3.8 GHz, and fmax = 221.5 ± 4.0 GHz, respectively. Thanks to the optimized stepper-based fabrication process, the fabricated InP DHBTs exhibit well-balanced high-frequency characteristics and excellent uniformity.
期刊介绍:
It is the aim of this journal to bring together in one publication outstanding papers reporting new and original work in the following areas: (1) applications of solid-state physics and technology to electronics and optoelectronics, including theory and device design; (2) optical, electrical, morphological characterization techniques and parameter extraction of devices; (3) fabrication of semiconductor devices, and also device-related materials growth, measurement and evaluation; (4) the physics and modeling of submicron and nanoscale microelectronic and optoelectronic devices, including processing, measurement, and performance evaluation; (5) applications of numerical methods to the modeling and simulation of solid-state devices and processes; and (6) nanoscale electronic and optoelectronic devices, photovoltaics, sensors, and MEMS based on semiconductor and alternative electronic materials; (7) synthesis and electrooptical properties of materials for novel devices.