• ETRI Journal
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• v.27 no.4
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• pp.439-445
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• 2005

We introduce a strained-SiGe technology adopting different thicknesses of Si cap layers towards low power and high performance CMOS applications. By simply adopting 3 and 7 nm thick Si-cap layers in n-channel and p-channel MOSFETs, respectively, the transconductances and driving currents of both devices were enhanced by 7 to 37% and 6 to 72%. These improvements seemed responsible for the formation of a lightly doped retrograde high-electron-mobility Si surface channel in nMOSFETs and a compressively strained high-hole-mobility $Si_{0.8}Ge_{0.2}$ buried channel in pMOSFETs. In addition, the nMOSFET exhibited greatly reduced subthreshold swing values (that is, reduced standby power consumption), and the pMOSFET revealed greatly suppressed 1/f noise and gate-leakage levels. Unlike the conventional strained-Si CMOS employing a relatively thick (typically > 2 ${\mu}m$) $Si_xGe_{1-x}$ relaxed buffer layer, the strained-SiGe CMOS with a very thin (20 nm) $Si_{0.8}Ge_{0.2}$ layer in this study showed a negligible self-heating problem. Consequently, the proposed strained-SiGe CMOS design structure should be a good candidate for low power and high performance digital/analog applications.

• Journal of the Korean Institute of Telematics and Electronics
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• v.23 no.6
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• pp.758-765
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• 1986

The design, fabrication and performance of vertical double diffused power MOSFET (VDMOS) were described. On the antimony (Sb) doped (~7x10**17 cm**-3) silicon substrate (N+), epitaxial layer(N-) was grown. The thickness and the resistivity of this layer were 32\ulcorner and about 12\ulcorner-cm, respectively. The P- channel length which was controlled by sequential P-/N+ double diffuison method was about 1~2 \ulcorner, and was processed with the self alignment of 21 \ulcorner width poly silicon. To improve the breakdown voltage with constant on-resistance (Ron) about 1\ulcorner, three P+ guard rings were laid out around main pattern. With chip size of 4800\ulcorner x4840 \ulcorner, the VDMOS has shown breakdown voltage of 410~440V, on-resistance within 1.0~1.2\ulcornerand the current capablity of more than 5A.

• Journal of the Korean Institute of Telematics and Electronics A
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• v.29A no.11
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• pp.91-96
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• 1992

The technology of LOCOS(LOCal Oxidation of Silicon) was used to form the island of SOI film. After this, the SOI film was recrystallized by CO$_2$ laser and metal gate nMOSFETs were fabricated on this SOI film and their electrical characteristics were measured. The kink effect was not nearly observed and edge channel effect was found in the SOI nMOSFETs. The threshold voltage was about 0.5V, the electron mobility was about 340cm$^2$V$\cdot$S and an ON/OFF ratio above 10$^{5}$ was obtained at V_{DS}$=4V. The electrical characteristics were improved by laser recrystallization.

• Proceedings of the IEEK Conference
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• 2000.06b
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• pp.20-23
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• 2000

We have investigated a process for the preparation of high-quality tantalum oxynitride ( $T_{a}$ $O_{x}$ $N_{y}$) via the N $H_3$ annealing of 7$_{a2}$ $O_{5}$, for use in gate dielectric applications. Compared with tantalum oxide (7$_{a2}$ $O_{5}$), a significant improvement in the dielectric constant was obtained by the N $H_3$ treatment. In addition, light reoxidation in a wet ambient at 45$0^{\circ}C$ resulted in a significantly reduced leakage current. We confirmed nitrogen incorporation in the tantalum oxynitride ( $T_{a}$ $O_{x}$ $N_{y}$ by Auger Electron Spectroscopy. By optimizing the nitridation and reoxidation process, we obtained an equivalent oxide thickness as thin as 1.6nm and a leakage current of less than 10mA/$\textrm{cm}^2$ at 1.5V..5V..5V..5V..5V..5V.

• The Transactions of the Korean Institute of Power Electronics
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• v.20 no.6
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• pp.558-565
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• 2015

Gallium nitride high-electron mobility transistor (GaN HEMT) is the strongest candidate for replacing Si MOSFET. Comparing the figure of merit (FOM) of GaN with the state-of-the-art super junction Si MOSFET, the FOM is much better because of the wide band gap characteristics and the heterojunction structure. Although GaN HEMT has many benefits for the power conversion system, the performance of the power conversion system with the GaN HEMT is sensitive because of its low threshold voltage ($V_{th}$) and even lower parasitic capacitance. This study examines the characteristics of a phase-shifted full-bridge dc-dc converter with cascode GaN HEMT. The problem of unoptimized dead time is analyzed on the basis of the output capacitance of GaN HEMT. In addition, the printed circuit board (PCB) layout consideration is analyzed to reduce the negative effects of parasitic inductance. A comparison of the experimental results is provided to validate the dead time and PCB layout analysis for a phase-shifted full-bridge dc-dc converter with cascode GaN HEMT.

• Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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• 2009.06a
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• pp.115-115
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• 2009

Current sensing in power semiconductors involves sensing of over-current in order to protect the device from harsh conditions. This technique is one of the most important functions in stabilizing power semiconductor device modules. The Power MOSFET is very efficient method with low power consumption, fast sensing speed and accuracy. In this paper, we have analyzed the characteristics of proposed sense FET and optimized its electrical characteristics to apply conventional 40 V power MOSFET by numerical and simulation analysis. The proposed sense FET has the n-drift doping concentration $1.5\times10^{14}\;cm^{-3}$, size of $600\;{\mu}m^2$ with $4.5\;{\Omega}$, and off-state leakage current below $50\;{\mu}A$. We offer the layout of the proposed Power MOSFET to process actually. The offerd design and optimization methods are meaningful, which the methods can be applied to the power devices having various breakdown voltages for protection.

• Journal of the Korean Institute of Telematics and Electronics D
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• v.36D no.4
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• pp.77-85
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• 1999

By assuming a linearly graded depletion edge approximation in the intrinsic MOS region and by taking into account the mobility variation dependent on both lateral and vertical fields, a physics-based analytical model for a short-channel(n-channel) MOSFET is suggested. Derived expressions for the threshold voltage and the drain current of typical MOSFET is structures could be used in a unified manner for all operating range. The threshold voltage was calculated by changing following variables : channel length, drain-source voltage, source-substrate voltage, p-substrate doping level, and oxide thickness. It is shown that the threshold voltage decreases almost exponentially as the channel length decreases. In addition, the short-channel threshold voltage roll-off, the channel length modulation and the electron mobility degradation can be derived within a satisfactory accuracy.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.6 no.1
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• pp.109-114
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• 2002

In this paper, we have presented the simulation results ah)ut threshold voltage for Si-based MOSFETs with channel length of nano scale. We simulated the Si-based n channel MOSFETs with gate lengths from 180 to 30 nm in accordance to the constant voltage scaling theory and the lateral scaling. These MOSFETs had the lightly doped drain(LDD) structure, which is used for the reduction of electric field magnitude and short channel effects at the drain region. The stronger electric field at this region is due to scaling down. We investigated and analyzed the threshold voltage of these devices. This analysis will provide insight into some applicable limitations at the ICs and used for basis data at VLSI.

• Journal of the Korean Vacuum Society
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• v.2 no.2
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• pp.188-198
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• 1993

We have developed a technique for growing thin oxides (6~10 nm) by the Last step TCA method. N-channel metal-oxide-semiconductor (n-MOS) capacitor and n-channel metal-oxide-semiconductor field-effect transistor's (MOSFET's) having a gate oxide with chlorine incorporated $SiO_2/Si$ interface have been analyzed by electrical measurements and physical methods, such as secondary ion mass spectrometry (SIMS) and electron spectroscopy for chemical analysis (ESCA). The gate oxide grown with the Last strp TCA method has good characteristics as follows: the electron mobility of the MOSFET's with the Last step TCA method was increased by about 7% and the defect density at the $SiO_2/Si$ interface decreases slightly compared with that with No TCA method. In reliability estimation, the breakdown field was 18 MV/cm, 0.6 MV/cm higher than that of the gate oxide with No TCA method, and the lifetime estimated by TDDB measurement was longer than 20 years. The device lifetime estimated from hot-carrier reliability was proven to be enhanced. As the results, the gate oxide having a $SiO_2/Si$ interface incorporated with chlorine has good characteristics. Our new technique of Last step TCA method may be used to improve the endurance and retention of MOSFET's and to alleviate the degradation of thin oxides in short-channel MOS devices.

• ETRI Journal
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• v.38 no.1
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• pp.133-140
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• 2016

This paper presents a method of parasitic inductance reduction for high-speed switching and high-efficiency operation of a cascode structure with a low-voltage enhancement-mode silicon (Si) metal-oxide-semiconductor field-effect transistor (MOSFET) and a high-voltage depletion-mode gallium nitride (GaN) fielde-ffect transistor (FET). The method is proposed to add a bonding wire interconnected between the source electrode of the Si MOSFET and the gate electrode of the GaN FET in a conventional cascode structure package to reduce the most critical inductance, which provides the major switching loss for a high switching speed and high efficiency. From the measured results of the proposed and conventional GaN cascode FETs, the rising and falling times of the proposed GaN cascode FET were up to 3.4% and 8.0% faster than those of the conventional GaN cascode FET, respectively, under measurement conditions of 30 V and 5 A. During the rising and falling times, the energy losses of the proposed GaN cascode FET were up to 0.3% and 6.7% lower than those of the conventional GaN cascode FET, respectively.