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Evaluation of a 'Field Cage' for Electric Field Control in GaN-Based HEMTs That Extends the Scalability of Breakdown into the kV Regime

IEEE Transactions on Electron Devices

Tierney, Brian D.; Dickerson, Jeramy; Reza, Shahed; Kaplar, Robert J.; Baca, Albert G.; Marinella, Matthew

A distributed impedance 'field cage' structure is proposed and evaluated for electric field control in GaN-based, lateral high electron mobility transistors operating as kilovolt-range power devices. In this structure, a resistive voltage divider is used to control the electric field throughout the active region. The structure complements earlier proposals utilizing floating field plates that did not employ resistively connected elements. Transient results, not previously reported for field plate schemes using either floating or resistively connected field plates, are presented for ramps of dVds/dt = 100 V/ns. For both dc and transient results, the voltage between the gate and drain is laterally distributed, ensuring that the electric field profile between the gate and drain remains below the critical breakdown field as the source-to-drain voltage is increased. Our scheme indicates promise for achieving the breakdown voltage scalability to a few kilovolts.

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Nuclear microprobe investigation of the effects of ionization and displacement damage in vertical, high voltage GaN diodes

Nuclear Instruments and Methods in Physics Research, Section B: Beam Interactions with Materials and Atoms

Vizkelethy, Gyorgy; King, Michael P.; Aktas, O.; Kizilyalli, I.C.; Kaplar, Robert J.

Radiation responses of high-voltage, vertical gallium-nitride (GaN) diodes were investigated using Sandia National Laboratories’ nuclear microprobe. Effects of the ionization and the displacement damage were studied using various ion beams. We found that the devices show avalanche effect for heavy ions operated under bias well below the breakdown voltage. The displacement damage experiments showed a surprising effect for moderate damage: the charge collection efficiency demonstrated an increase instead of a decrease for higher bias voltages.

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Ohmic contacts to Al-rich AlGaN heterostructures

Physica Status Solidi (A) Applications and Materials Science

Douglas, Erica A.; Reza, Shahed; Sanchez, Carlos A.; Allerman, Andrew A.; Klein, Brianna A.; Armstrong, Andrew A.; Kaplar, Robert J.; Baca, Albert G.; Koleske, Daniel

Due to the ultra-wide bandgap of Al-rich AlGaN, up to 5.8 eV for the structures in this study, obtaining low resistance ohmic contacts is inherently difficult to achieve. A comparative study of three different fabrication schemes is presented for obtaining ohmic contacts to an Al-rich AlGaN channel. Schottky-like behavior was observed for several different planar metallization stacks (and anneal temperatures), in addition to a dry-etch recess metallization contact scheme on Al0.85Ga0.15N/Al0.66Ga0.34N. However, a dry etch recess followed by n+-GaN regrowth fabrication process is reported as a means to obtain lower contact resistivity ohmic contacts on a Al0.85Ga0.15N/Al0.66Ga0.34N heterostructure. Specific contact resistivity of 5 × 10−3 Ω cm2 was achieved after annealing Ti/Al/Ni/Au metallization.

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Imaging the Impact of Proton Irradiation on Edge Terminations in Vertical GaN pin Diodes

IEEE Electron Device Letters

Celio, Kimberlee C.; King, Michael P.; Dickerson, Jeramy; Vizkelethy, Gyorgy; Armstrong, Andrew A.; Fischer, Arthur J.; Allerman, Andrew A.; Kaplar, Robert J.; Aktas, Ozgur; Kizilyalli, Isik C.; Talin, Albert A.; Leonard, Francois

Devices based on GaN have shown great promise for high power electronics, including their potential use as radiation tolerant components. An important step to realizing high power diodes is the design and implementation of an edge termination to mitigate field crowding, which can lead to premature breakdown. However, little is known about the effects of radiation on edge termination functionality. We experimentally examine the effects of proton irradiation on multiple field ring edge terminations in high power vertical GaN pin diodes using in operando imaging with electron beam induced current (EBIC). We find that exposure to proton irradiation influences field spreading in the edge termination as well as carrier transport near the anode. By using depth-dependent EBIC measurements of hole diffusion length in homoepitaxial n-GaN we demonstrate that the carrier transport effect is due to a reduction in hole diffusion length following proton irradiation.

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Analysis of 2D transport and performance characteristics for lateral power devices based on AlGaN alloys

ECS Journal of Solid State Science and Technology

Coltrin, Michael E.; Baca, Albert G.; Kaplar, Robert J.

Predicted lateral power device performance as a function of alloy composition is characterized by a standard lateral device figure-of-merit (LFOM) that depends on mobility, critical electric field, and sheet carrier density. The paper presents calculations of AlGaN electron mobility in lateral devices such as HEMTs across the entire alloy composition range. Alloy scattering and optical polar phonon scattering are the dominant mechanisms limiting carrier mobility. Due to the significant degradation of mobility from alloy scattering, at room temperature Al fractions greater than about 85% are required for improved LFOM relative to GaN using a conservative sheet charge density of 1 × 1013 cm−2. However, at higher temperatures at which AlGaN power devices are anticipated to operate, this “breakeven” composition decreases to about 65% at 500 K, for example. For high-frequency applications, the Johnson figure-of-merit (JFOM) is the relevant metric to compare potential device performance across materials platforms. At room temperature, the JFOM for AlGaN alloys is predicted to surpass that of GaN for Al fractions greater than about 40%.

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Module-level paralleling of vertical GaN PiN diodes

WiPDA 2016 - 4th IEEE Workshop on Wide Bandgap Power Devices and Applications

Flicker, Jack D.; Brocato, Robert W.; Delhotal, Jarod J.; Neely, Jason C.; Sumner, Bjorn; Dickerson, Jeramy; Kaplar, Robert J.

The effects of paralleling low-current vertical Gallium Nitride (v-GaN) diodes in a custom power module are reported. Four paralleled v-GaN diodes were demonstrated to operate in a buck converter at 1.3 Apeak (792 mArms) at 240 V and 15 kHz switching frequency. Additionally, high-fidelity SPICE simulations demonstrate the effects of device parameter variation on power sharing in a power module. The device parameters studied were found to have a sub-linear relationship with power sharing, indicating a relaxed need to bin parts for paralleling. This result is very encouraging for power electronics based on low-current v-GaN and demonstrates its potential for use in high-power systems.

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Review—Ultra-Wide-Bandgap AlGaN Power Electronic Devices

ECS Journal of Solid State Science and Technology

Kaplar, Robert J.; Allerman, Andrew A.; Armstrong, Andrew A.; Crawford, Mary H.; Dickerson, Jeramy; Fischer, Arthur J.; Baca, Albert G.; Douglas, Erica A.

“Ultra” wide-bandgap semiconductors are an emerging class of materials with bandgaps greater than that of gallium nitride (EG > 3.4 eV) that may ultimately benefit a wide range of applications, including switching power conversion, pulsed power, RF electronics, UV optoelectronics, and quantum information. This paper describes the progress made to date at Sandia National Laboratories to develop one of these materials, aluminum gallium nitride, targeted toward high-power devices. The advantageous material properties of AlGaN are reviewed, questions concerning epitaxial growth and defect physics are covered, and the processing and performance of vertical- and lateral-geometry devices are described. The paper concludes with an assessment of the outlook for AlGaN, including outstanding research opportunities and a brief discussion of other potential applications.

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Inductively coupled BCl3/Cl2 /Ar plasma etching of Al-rich AlGaN

Journal of Vacuum Science and Technology. A, Vacuum, Surfaces and Films

Douglas, Erica A.; Sanchez, Carlos A.; Kaplar, Robert J.; Allerman, Andrew A.; Baca, Albert G.

Varying atomic ratios in compound semiconductors is well known to have large effects on the etching properties of the material. The use of thin device barrier layers, down to 25 nm, adds to the fabrication complexity by requiring precise control over etch rates and surface morphology. The effects of bias power and gas ratio of BCl3 to Cl2 for inductively coupled plasma etching of high Al content AlGaN were contrasted with AlN in this study for etch rate, selectivity, and surface morphology. Etch rates were greatly affected by both bias power and gas chemistry. Here we detail the effects of small variations in Al composition for AlGaN and show substantial changes in etch rate with regards to bias power as compared to AlN.

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Results 176–200 of 346
Results 176–200 of 346
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