Your search keyword '"Shiozaki, Koji"' showing total 14 results

1. Influence of HfO2 and SiO2 interfacial layers on the characteristics of n-GaN/HfSiOx capacitors using plasma-enhanced atomic layer deposition.

Author

Nabatame, Toshihide, Maeda, Erika, Inoue, Mari, Hirose, Masafumi, Irokawa, Yoshihiro, Ohi, Akihiko, Ikeda, Naoki, Onaya, Takashi, Shiozaki, Koji, Ochi, Ryota, Hashizume, Tamotsu, and Koide, Yasuo

Subjects

ATOMIC layer deposition, ELECTRIC breakdown, CAPACITORS, STRAY currents, PLASMA gases

Abstract

We investigated the growth per cycle (GPC) for SiO2 and HfO2 on n-GaN/native oxide and p-Si/SiO2 substrates by plasma-enhanced atomic layer deposition using tris(dimethylamino)silane and tetrakis(dimethylamino)hafnium precursors, respectively, and O2 plasma gases. On the basis of the estimated GPC, we also examined the characteristics of n-GaN/Hf0.57Si0.43Ox/Pt capacitors with an inserted interfacial layer (IL) such as subnanometer-thick HfO2 and SiO2. We found that the GPC for SiO2 on n-GaN/native oxide was slightly smaller than that on p-Si/SiO2, whereas the GPC for HfO2 was the same on both substrates. The GPC for ALD-SiO2 could be reasonably plotted on the basis of the relationship between the GPC and the difference in electronegativity between the metal and oxygen in the metal-O underlayers including native oxide (Ga2O3) on GaN. On the basis of the GPC on n-GaN, Hf0.57Si0.43Ox (23 nm) capacitors were fabricated without and with a HfO2-IL (0.3 and 0.5 nm) or SiO2-IL (0.3 and 0.6 nm). These capacitors exhibited similar leakage current properties and a high breakdown electric field greater than 8.3 MV cm−1. No frequency dispersion and a flatband voltage (Vfb) hysteresis smaller than 50 mV were observed for all of the capacitors. Compared with the SiO2-IL [Si-rich HfSiOx (Si: > 0.43)] capacitors, the HfO2-IL [Hf-rich HfSiOx (Hf: > 0.57)] capacitors showed a smaller interface state density [(1.2–1.7) × 1011 cm−2 eV−1 at −0.4 eV from the conduction band] and a smaller negative Vfb shift. Therefore, the Hf-rich HfSiOx (Hf: > 0.57) grown using a HfO2-IL at the n-GaN/HfSiOx interface plays a substantial role in improving the electrical properties of n-GaN/HfSiOx capacitors. [ABSTRACT FROM AUTHOR]

Published

2021

2. Gate controllability of HfSiOx/AlGaN/GaN MOS high-electron-mobility transistor.

Author

Ochi, Ryota, Maeda, Erika, Nabatame, Toshihide, Shiozaki, Koji, Sato, Taketomo, and Hashizume, Tamotsu

Subjects

MODULATION-doped field-effect transistors, ATOMIC layer deposition, CONTROLLABILITY in systems engineering, DENSITY of states, HAFNIUM, HIGH temperatures

Abstract

Hafnium silicate (HfSiOx) has been applied to AlGaN/GaN high-electron-mobility transistors (HEMTs) as a high κ gate dielectric. The (HfO2)/(SiO2) laminate structure was deposited on the AlGaN surface by a plasma-enhanced atomic layer deposition, followed by a post-deposition annealing at 800 °C. The HfSiOx-gate HEMT showed good transfer characteristics with a high transconductance expected from its κ value and a subthreshold swing of 71 mV/decade. For the metal–oxide-semiconductor (MOS) HEMT diode, we observed excellent capacitance–voltage (C–V) characteristics with negligible frequency dispersion. The detailed C–V analysis showed low state densities on the order of 1011 cm−2 eV−1 at the HfSiOx/AlGaN interface. In addition, excellent operation stability of the MOS HEMT was observed at high temperatures up to 150 °C. [ABSTRACT FROM AUTHOR]

Published

2020

3. Hybrid decision and data adaptive antenna array processing for collision avoidance radar.

Author

Subotic, Nikola S., Li, Liping, Schmalenberg, Paul, Lee, Jae S., and Shiozaki, Koji

Published

2015

4. Double-sided nickel-tin transient liquid phase bonding for double-sided cooling.

Author

Yoon, Sang Won, Shiozaki, Koji, and Kato, Takehiro

Published

2014

5. A 77–81-GHz 16-Element Phased-Array Receiver With \pm \50^\circ Beam Scanning for Advanced Automotive Radars.

Author

Ku, Bon-Hyun, Schmalenberg, Paul, Inac, Ozgur, Gurbuz, Ozan Dogan, Lee, Jae Seung, Shiozaki, Koji, and Rebeiz, Gabriel M.

Subjects

ROAD vehicle radar, PHASED array antennas, AZIMUTH, SILICON germanium integrated circuits, AUTOMOTIVE engineering, MILLIMETER waves

Abstract

A 16-element phased-array receiver has been developed for advanced W-band automotive radars. The phased-array receiver is based on a single SiGe chip with RF beamforming capabilities, which is packaged using low-cost bond-wire techniques and attached to a 16-element linear microstrip array. The antenna results in a directivity of 29.3 dB and a gain of 28.0 dB at 77–81 GHz, and can be scanned to \pm \50^\circ in the azimuth plane in \sim \ 1^\circ steps. The packaging details are presented together with the steps taken to ensure a wideband impedance match and low coupling between the phased-array channels. Gain measurements done at 79 GHz agree well with simulations. The 16-element phased array receiver was used with a 2-element frequency-modulated continuous-wave transmitter at 76.5–77 GHz and high-resolution millimeter-wave images were obtained. The work shows that complex millimeter-wave phased arrays can be packaged using traditional bond-wire techniques, and can be a powerful solution for advanced automotive radars. [ABSTRACT FROM AUTHOR]

Published

2014

6. A SiGe-based 16-channel phased array radar system at W-Band for automotive applications.

Author

Schmalenberg, Paul, Lee, Jae Seung, and Shiozaki, Koji

Published

2013

7. Decision adaptive antenna array processing for collision avoidance radar.

Author

Subotic, Nikola S., Kourous, Helen, Wilson, Brian, Li, Liping, Schmalenberg, Paul, Lee, Jae S., and Shiozaki, Koji

Published

2013

8. A SiGe-based 16-channel phased array radar system at W-Band for automotive applications.

Author

Schmalenberg, Paul, Lee, Jae Seung, and Shiozaki, Koji

Published

2013

9. A 16-element 77–81-GHz phased array for automotive radars with ±50° beam-scanning capabilities.

Author

Ku, Bon-Hyun, Schmalenberg, Paul, Kim, Sang Young, Kim, Choul-Young, Inac, Ozgur, Lee, Jae Seung, Shiozaki, Koji, and Rebeiz, Gabriel M.

Abstract

This paper presents the first 16-element 77–81 GHz phased array receiver for automotive radars. The silicon phased array chip is packaged using very low-cost techniques, and is attached to a 16-element linear microstrip antenna array. The packaging is designed to result in < −28 dB coupling between the channels even with wirebonds. The measured patterns show scanning to ±50o and agree well with simulations. The 16-element phased array receiver has been implemented with a transmitter and shows detailed images of targets and scenes in outdoor driving scenarios. [ABSTRACT FROM PUBLISHER]

Published

2013

10. High current and high frequency planar inductor loss measurement and analysis.

Author

Toshiyuki, Ken, Guo, Yuanbo, Shiozaki, Koji, Xu, Di, and Ngo, Khai

Published

2013

11. Highly reliable nickel-tin transient liquid phase bonding technology for high temperature operational power electronics in electrified vehicles.

Author

Yoon, Sang Won, Shiozaki, Koji, Yasuda, Satoshi, and Glover, Michael D.

Abstract

This paper presents an approach to nickel-tin transient liquid phase (TLP) bonding that provides high reliability for high temperature operational power electronics in electrified vehicles. The need for automotive power electronics to operate at high temperature presents significant challenges in terms of the packaging and bonding technology used. Transient liquid phase (TLP) bonding is one attachment approach that addresses these challenges. The Ni/Sn TLP bonding process exhibits a number of desirable characteristics, including a good CTE match with silicon and silicon carbide, popularity in conventional power electronics, low cost, and uniform alloy formation. The work herein presents a Ni/Sn TLP bonding technology (ready for high temperature operation up to 200°C) as applied to large size silicon power devices (12 mm × 9 mm). Analysis indicates that the resulting bondline is uniformly composed of Ni3Sn4 alloy throughout. This bonding approach has exhibited excellent reliability for bonded devices after 1000 thermal cycles from −40 to 200°C. [ABSTRACT FROM PUBLISHER]

Published

2012

12. A High-Density, High-Efficiency, Isolated On-Board Vehicle Battery Charger Utilizing Silicon Carbide Power Devices.

Author

Whitaker, Bret, Barkley, Adam, Cole, Zach, Passmore, Brandon, Martin, Daniel, McNutt, Ty R., Lostetter, Alexander B., Jae Seung Lee, and Shiozaki, Koji

Subjects

BATTERY chargers, SILICON carbide, WIDE gap semiconductors, ELECTRIC vehicle batteries, POWER electronics, DC-to-DC converters

Abstract

This paper presents an isolated on-board vehicular battery charger that utilizes silicon carbide (SiC) power devices to achieve high density and high efficiency for application in electric vehicles (EVs) and plug-in hybrid EVs (PHEVs). The proposed level 2 charger has a two-stage architecture where the first stage is a bridgeless boost ac-dc converter and the second stage is a phase-shifted full-bridge isolated dc-dc converter. The operation of both topologies is presented and the specific advantages gained through the use of SiC power devices are discussed. The design of power stage components, the packaging of the multichip power module, and the system-level packaging is presented with a primary focus on system density and a secondary focus on system efficiency. In this work, a hardware prototype is developed and a peak system efficiency of 95% is measured while operating both power stages with a switching frequency of 200 kHz. A maximum output power of 6.1 kW results in a volumetric power density of 5.0 kW/L and a gravimetric power density of 3.8 kW/kg when considering the volume and mass of the system including a case. [ABSTRACT FROM AUTHOR]

Published

2014

13. Reliable and repeatable bonding technology for high temperature automotive power modules for electrified vehicles.

Author

Sang Won Yoon, Glover, Michael D., Mantooth, H Alan, and Shiozaki, Koji

Subjects

RELIABILITY in engineering, CHEMICAL bonds, ELECTRIC vehicles, HIGH temperatures, ELECTRIC conductivity, SHEET metal, THERMAL conductivity, COPPER compounds

Abstract

e (for fabrication of advanced structures). Cu-Sn TLP bonding is employed herein because of its high remelting temperature and desirable thermal and electrical conductivities. The bonding starts with a stack of Cu-Sn-Cu metal layers that eventually transforms to Cu-Sn alloys. As the alloys have melting temperatures (Cu3Sn: > 600 ?C, Cu6Sn5: > 400 ?C) significantly higher than the process temperature, the process can be repeated without damaging previously bonded layers. A Cu-Sn TLP bonding process was developed using thin Sn metal sheets inserted between copper layers on silicon die and direct bonded copper substrates, emulating the process used to construct automotive power modules. Bond quality is characterized using (1) proof-of-concept fabrication, (2) material identification using scanning electron microscopy and energy-dispersive x-ray spectroscopy analysis, and (3) optical analysis using optical microscopy and scanning acoustic microscope. The feasibility of multiple-sided Cu-Sn TLP bonding is demonstrated by the absence of bondline damage in multiple test samples fabricated with double- or four-sided bonding using the TLP bonding process. [ABSTRACT FROM AUTHOR]

Published

2013

14. HfSiOx-gate GaN MOS-HEMTs for RF power transistor.

Author

Fujioka, Hiroshi, Morkoç, Hadis, Schwarz, Ulrich T., Hashizume, Tamotsu, Ochi, Ryota, Maeda, Erika, Nabatame, Toshihide, Shiozaki, Koji, and Sato, Taketomo

Published

2021