1200 V SiC vertical‐channel‐JFETs and cascode switches

Veliadis, Victor

doi:10.1002/pssa.200925069

Cited by 8 publications

(3 citation statements)

References 31 publications

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“…41 The use of sub-micron fin channels in WBG JFETs has allowed for a shift from the D-mode to Emode operation. 77,78 As the fin dimension reduces in SiC Fin-JFETs, however, the sidewall ion implantation used for p-gate formation would degrade the channel mobility, which offsets the benefits of high channel density and results in a higher 𝑅 . This processing issue is not present for GaN Fin-JFETs due to their implantation-free fabrication.…”

Section: Finfet and Trigatementioning

confidence: 99%

Multidimensional device architectures for efficient power electronics

2022

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Power semiconductor devices are key to delivering high efficiency energy conversion in power electronics systems, which is critical towards efforts in reducing energy loss, cutting carbon dioxide emissions and creating more sustainable technology. While the use of wide or ultra-wide bandgap materials will be required in order to create improved power devices, multidimensional architectures can also improve performance, regardless of the underlying material technology. In particular, multidimensional device architectures -such as superjunction, multi-channel and multi-gate technologies -can enable advances in the speed, efficiency, and form factor of power electronics systems. Here we review the development of multidimensional device architectures for efficient power electronics. We explore the rationale for using multidimensional architectures and the different architectures available. We also consider the performance limits, scaling, and material figure-of-merits of the architectures, and identify key technological challenges that need to be addressed in order to realize the full potential of the approach.

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Section: Finfet and Trigatementioning

confidence: 99%

Multidimensional device architectures for efficient power electronics

2022

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“…Both normally-OFF and normally-ON SiC JFETs have been demonstrated. However, it was later found that the narrow and implanted fin channel in normally-OFF SiC JFETs makes their R ON several times higher than the normally-ON counterparts [45]. As a result, the commercially available SiC JFET is normally-ON; it is co-packaged with a Si MOSFET in a cascode configuration to realize the normally-OFF operation.…”

Section: Gan Materials At 25mentioning

confidence: 99%

1.2-kV Vertical GaN Fin-JFETs: High-Temperature Characteristics and Avalanche Capability

Liu

Xiao

Zhang

et al. 2021

IEEE Trans. Electron Devices

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This work describes the high-temperature performance and avalanche capability of normally-OFF 1.2-kV-class vertical gallium nitride (GaN) fin-channel junction field-effect transistors (Fin-JFETs). The GaN Fin-JFETs were fabricated by NexGen Power Systems, Inc. on 100-mm GaN-on-GaN wafers. The threshold voltage (V TH) is over 2 V with less than 0.15 V shift from 25 • C to 200 • C. The specific ON-resistance (R ON) increases from 0.82 at 25 • C to 1.8 m•cm 2 at 200 • C. The thermal stability of V TH and R ON are superior to the values reported in SiC MOSFETs and JFETs. At 200 • C, the gate leakage and drain leakage currents remain below 100 μA at −7-V gate bias and 1200-V drain bias, respectively. The gate leakage current mechanism is consistent with carrier hopping across the lateral p-n junction. The high-bias drain leakage current can be well described by the Poole-Frenkel (PF) emission model. An avalanche breakdown voltage (BV AVA) with positive temperature coefficient is shown in both the quasistatic I-V sweep and the unclamped inductive switching (UIS) tests. The UIS tests also reveal a BV AVA over 1700 V and a critical avalanche energy (E AVA) of 7.44 J/cm 2 , with the E AVA comparable to that of state-of-the-art SiC MOSFETs. These results show the great potentials of vertical GaN Fin-JFETs for medium-voltage power electronics applications.

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“…Junction Field Effect Transistor (JFET) has been widely studied by many research groups from the end of the'90s, and nowadays has entered the commercial market. This is a semiconductor device based on a control of the drain current with the aid of an electric field generated by a bias between gate and source [1]. It is based on the conductive channel of which the conductance can be modulated by means of applied voltage to the gate.…”

Section: Introductionmentioning

confidence: 99%

Structural and electrical characterization of the 4H-SiC based junction field effect transistor (JFET)

Shili

Karoui

Gharbi

et al. 2013

2013 International Conference on Electrical Engineering and Software Applications

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The main focus of our work is the characterization and structural study of 4H-silicon carbide (SiC) normally-off vertical junction field effect transistor (JFET). We will determine the experimental static I ds-V ds characteristics under temperature variation. In order to achieve a better description of SiC and metal interface properties, many interesting parameters related to the material and to the device performance have been obtained from these measurements. Simulation has been used to correlate obtained results to physical parameters. When the temperature increases to 300°C, the R DS(ON) increase to 700 mΩ and the saturation drain source current decreases up to 14A.

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1200 V SiC vertical‐channel‐JFETs and cascode switches

Cited by 8 publications

References 31 publications

Multidimensional device architectures for efficient power electronics

Multidimensional device architectures for efficient power electronics

1.2-kV Vertical GaN Fin-JFETs: High-Temperature Characteristics and Avalanche Capability

Structural and electrical characterization of the 4H-SiC based junction field effect transistor (JFET)

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