Chinmoy Nath Saha scite author profile

This Letter reports a high performance β-Ga2O3 thin channel MOSFET with T gate and degenerately doped (n++) source/drain contacts regrown by metal organic chemical vapor deposition. Highly scaled T-gate with a gate length of 160–200 nm was fabricated to achieve enhanced RF performance and passivated with 200 nm silicon nitride. Peak drain current (ID,MAX) of 285 mA/mm and peak transconductance (gm) of 52 mS/mm were measured at 10 V drain bias with 23.5 Ω mm on resistance (RON). Metal/n++ contact resistance of 0.078 Ω mm was extracted from transfer length measurements. RON is possibly dominated by interface resistance between channel and highly doped n++ regrown layer. A gate-to-drain breakdown voltage of 192 V is measured for LGD = 355 nm resulting in average breakdown field (EAVG) of 5.4 MV/cm. This EAVG is the highest reported among all sub-micron gate length lateral FETs. Current gain cut off frequency (fT) of 11 GHz and record power gain cut off frequency (fMAX) of approximately 48 GHz were extracted from small signal measurements. fT is limited by DC-RF dispersion due to interface traps which needs further investigation. The fT·VBR product is 2.112 THz V for 192 V breakdown voltage. Device surpasses the switching figure of merit of Silicon and competitive with mature wide bandgap devices.

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Temperature dependent pulsed IV and RF characterization of β-(AlxGa1−x)2O3/Ga2O3 hetero-structure FET with ex situ passivation

Saha

Vaidya

Singisetti

2022

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In this work, we report a study of the temperature dependent pulsed current voltage and RF characterization of [Formula: see text]-(AlxGa1−x)2O3/Ga2O3 hetero-structure FETs (HFETs) before and after silicon nitride (Si3N4) passivation. Under sub-microsecond pulsing, a moderate DC-RF dispersion (current collapse) is observed before passivation in gate lag measurements, while no current collapse is observed in the drain lag measurements. The dispersion in the gate lag is possibly attributed to interface traps in the gate–drain access region. DC-RF dispersion did not show any strong dependence on the pulse widths. Temperature dependent RF measurements up to 250 °C do not show degradation in the cutoff frequencies. After Si3N4 deposition at 350 °C, a shift of the threshold voltage is observed which changed the DC characteristics. However, the current collapse is eliminated; at 200 ns pulse widths, a 50% higher current is observed compared to the DC at high drain voltages. No current collapse is observed even at higher temperatures. RF performance of the passivated devices does not show degradation. These results show that ex situ deposited Si3N4 is a potential candidate for passivation of [Formula: see text]-(AlxGa1−x)2O3/Ga2O3 HFETs.

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Analytical modeling and performance analysis for symmetric double gate stack-oxide junctionless field effect transistor in subthreshold region

Fabiha

Saha

Islam

2017

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Frequency Stability Enhancement of a Large-Scale PV Integrated Grid

Jawad

Naim

Saha

et al. 2020

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