Papers by Keyword: P-Channel

Abstract: The fabrication of CMOS devices in SiC is important for both a higher operating temperature capability and the integration with SiC power devices. In this work, n-channel and p-channel signal MOSFETs have been successfully fabricated using a process technology fully compatible with our HV SiC VDMOS technology. A preliminary SiC CMOS inverter has been also integrated. The gate oxide configuration includes the use of Boron to improve SiO₂/SiC. Electrical characterizations have been carried out at room temperature and a summary of the results is presented. The biggest challenge is to balance the n-type and p-type MOSFETs not only in area but also in V_th value.

Abstract: High-voltage SiC p-channel insulated-gate bipolar transistors (p-IGBT) utilizing current-spreading layer (CSL) formed by ion implantation are fabricated and their properties characterized. A high blocking voltage of 15 kV is achieved at room temperature by optimizing the JFET length. An ampere-class p-IGBT exhibited a low forward voltage drop of 8.5 V at 100 A/cm² and a low differential specific on-resistance of 33 mΩ cm² at 250 °C, while these values were high at room temperature. For further reduction of the forward voltage drop in the on-state and temperature stability, the temperature dependence of the JFET effect and carrier lifetime in p-IGBTs are investigated. Optimization of the JFET length using an epitaxial CSL, instead of applying ion implantation and lifetime enhancement, could lead to a further reduction of the forward voltage drop.

Abstract: We fabricated and characterized an ultrahigh voltage (>10kV) p-channel silicon carbide insulated gate bipolar transistor (SiC-IGBT) with high channel mobility. Higher field-effect channel mobility of 13.5 cm²/Vs was achieved by the combination of adopting an n-type base layer with a retrograde doping profile and additional wet re-oxidation annealing (wet-ROA) at 1100°C in the gate oxidation process. The on-state characteristics of the p-channel SiC-IGBT at 200°C showed the low differential specific on-resistance of 24 mΩcm² at V_G = -20 V. The forward blocking voltage of the p-channel SiC-IGBT at 25°C was 10.2 kV a the leakage current density of 1.0 μA/cm².

Abstract: Fabricated were 4H-SiC p-channel MOSFETs in two types of ion-implanted n-well regions and in the n-type substrate as a control. Effects of the n-well structure on the electrical properties were investigated. P-channel MOSFETs fabricated in the uniform doped n-well by using multiple ion-implantations showed inferior on-state characteristics to that of the control MOSFET, while those fabricated in the retrograde n-wells by using single-shot ion-implantation without additional implantation to form the surface p-type region indicated improved channel properties. The Vth values were controlled by the impurity concentration and depth of the surface p-type region, and the values of channel mobility were nearly equal to that of the control MOSFET. Good sub-threshold characteristics for the type II devices were demonstrated.

Abstract: We investigated the 4H-SiC C-face MOS interface properties around valence-band, and fabricated 4H-SiC C-face p-channel MOSFETs for the first time. For C-face p-channel MOSFETs, relatively low-temperature wet-gate-oxidation was preferable. Post-deposition-annealing for contact metal was found to degrade the C-face MOS interface around valence-band. Low-temperature (800°C) PDA in hydrogen including ambient was effective to some extent in order to suppress the degradation owing annealing. We obtained C-face p-channel MOSFET with normal FET operation by utilizing 900°C wet-gate-oxidation and 800°C PDA in He-H2 forming gas ambient.

Abstract: P-channel MOSFETs have been fabricated on 4H-SiC (0001) face as well as on 4H-SiC (03-38) and (11-20) faces. The gate oxides were formed by thermal oxidation in dry N2O ambient, which is widely accepted to improve the performance of n-channel SiC MOSFETs. The p-channel SiC MOSFETs with N2O-grown oxides on 4H-SiC (0001), (03-38), and (11-20) faces show a channel mobility of 7 cm2/Vs, 11 cm2/Vs, and 17 cm2/Vs, respectively. From the quasi-static C-V curves measured by using gate-controlled diodes, the interface state density was calculated by an original method. The interface state density was the lowest at the SiO2/4H-SiC (03-38) interface (about 1x1012 cm-2eV-1 at EV + 0.2 eV). The authors have applied deposited oxides to the 4H-SiC p-channel MOSFETs. The (0001), (03-38), and (11-20) MOSFETs with deposited oxides exhibit a channel mobility of 10 cm2/Vs, 13 cm2/Vs, and 17 cm2/Vs, respectively. The deposited oxides are one of effective approaches to improve both n-channel and p-channel 4H-SiC MOS devices.

Abstract: DC characteristics of 4H-SiC p-channel IGBTs capable of blocking -12 kV and conducting -0.4 A (-100 A/cm2) at a forward voltage of -5.2 V at 25°C are demonstrated for the first time. A record low differential on-resistance of 14 mW×cm2 was achieved with a gate bias of -20 V indicating a strong conductivity modulation in the p-type drift region. A moderately doped current enhancement layer grown on the lightly doped drift layer effectively reduces the JFET resistance while maintains a high carrier lifetime for conductivity modulation. A hole MOS channel mobility of 12.5 cm2/V-s at -20 V of gate bias was measured with a MOS threshold voltage of -5.8 V. The blocking voltage of -12 kV was achieved by Junction Termination Extension (JTE).