Reet Chaudhuri scite author profile

Reet Chaudhuri

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5Publications

244Citation Statements Received

192Citation Statements Given

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Affiliations

Cornell University, Ithaca College

Publications

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A polarization-induced 2D hole gas in undoped gallium nitride quantum wells

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et al. 2019

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A high-conductivity two-dimensional (2D) hole gas, analogous to the ubiquitous 2D electron gas, is desirable in nitride semiconductors for wide-bandgap p-channel transistors. We report the observation of a polarization-induced high-density 2D hole gas in epitaxially grown gallium nitride on aluminium nitride and show that such hole gases can form without acceptor dopants. The measured high 2D hole gas densities of about 5 × 1013 per square centimeters remain unchanged down to cryogenic temperatures and allow some of the lowest p-type sheet resistances among all wide-bandgap semiconductors. The observed results provide a probe for studying the valence band structure and transport properties of wide-bandgap nitride interfaces.

Prospects for Wide Bandgap and Ultrawide Bandgap CMOS Devices

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et al. 2020

IEEE Trans. Electron Devices

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High Breakdown Voltage in RF AlN/GaN/AlN Quantum Well HEMTs

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et al. 2019

IEEE Electron Device Lett.

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Next generation electronics on the ultrawide-bandgap aluminum nitride platform

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et al. 2021

Semicond. Sci. Technol.

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Gallium nitride high-electron-mobility transistors (GaN HEMTs) are at a point of rapid growth in defense (radar, SATCOM) and commercial (5G and beyond) industries. This growth also comes at a point at which the standard GaN heterostructures remain unoptimized for maximum performance. For this reason, we propose the shift to the aluminum nitride (AlN) platform. AlN allows for smarter, highly-scaled heterostructure design that will improve the output power and thermal management of III-nitride amplifiers. Beyond improvements over the incumbent amplifier technology, AlN will allow for a level of integration previously unachievable with GaN electronics. State-of-the-art high-current p-channel FETs, mature filter technology, and advanced waveguides, all monolithically integrated with an AlN/GaN/AlN HEMT, is made possible with AlN. It is on this new AlN platform that nitride electronics may maximize their full high-power, high-speed potential for mm-wave communication and high-power logic applications.

Gate-Recessed E-mode p-Channel HFET With High On-Current Based on GaN/AlN 2D Hole Gas

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et al. 2018

IEEE Electron Device Lett.

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High-performance p-channel transistors are crucial to implementing efficient complementary circuits in widebandgap electronics, but progress on such devices has lagged far behind their powerful electron-based counterparts due to the inherent challenges of manipulating holes in wide-gap semiconductors. Building on recent advances in materials growth, this work sets simultaneous records in both on-current (10 mA/mm) and on-off modulation (four orders) for the GaN/AlN widebandgap p-FET structure. A compact analytical pFET model is derived, and the results are benchmarked against the various alternatives in the literature, clarifying the heterostructure trade-offs to enable integrated wide-bandgap CMOS for nextgeneration compact high-power devices.

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