• JSTS:Journal of Semiconductor Technology and Science
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• v.8 no.4
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• pp.302-310
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• 2008

This paper puts forward an advanced consideration on the design of scaled multiple-gate FET (MuGFET); the aspect ratio ($R_{h/w}$) of the fin height (h) to fin width (w) of MuGFET is considered with the aid of 3-D device simulations. Since any change in the aspect ratio must consider the trade-off between drivability and short-channel effects, it is shown that optimization of the aspect ratio is essential in designing MuGFET's. It is clearly seen that the triple-gate (TG) FET is superior to the conventional FinFET from the viewpoints of drivability and short-channel effects as was to be expected. It can be concluded that the guideline of w < L/3, where L is the channel length, is essential to suppress the short-channel effects of TG-FET.

• JSTS:Journal of Semiconductor Technology and Science
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• v.10 no.2
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• pp.134-142
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• 2010

A comparative study on the trade-off between the drive current and the total gate capacitance in double-gate (DG) and triple-gate (TG) FinFETs is performed by using 3-D device simulation. As the first result, we found that the optimum ratio of the hardmask oxide thickness ($T_{mask}$) to the sidewall oxide thickness ($T_{ox}$) is $T_{mask}/T_{ox}$=10/2 nm for the minimum logic delay ($\tau$) while $T_{mask}/T_{ox}$=5/1~2 nm for the maximum intrinsic gate capacitance coupling ratio (ICR) with the fixed channel length ($L_G$) and the fin width ($W_{fin}$) under the short channel effect criterion. It means that the TG FinFET is not under the optimal condition in terms of the circuit performance. Second, under optimized $T_{mask}/T_{ox}$, the propagation delay ($\tau$) decreases with the increasing fin height $H_{fin}$. It means that the FinFET-based logic circuit operation goes into the drive current-dominant regime rather than the input gate load capacitance-dominant regime as $H_{fin}$ increases. In the end, the sensitivity of $\Delta\tau/{\Delta}H_{fin}$ or ${{\Delta}I_{ON}}'/{\Delta}H_{fin}$ decreases as $L_G/W_{fin}$ is scaled-down. However, $W_{fin}$ should be carefully designed especially in circuits that are strongly influenced by the self-capacitance or a physical layout because the scaling of $W_{fin}$ is followed by the increase of the self-capacitance portion in the total load capacitance.

• Transactions on Electrical and Electronic Materials
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• v.17 no.6
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• pp.329-334
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• 2016

In this work, the temperature dependence of electrical parameters of nanoscale SOI (silicon-on-insulator) TG (triple gate) n-FinFET (n-channel Fin field effect transistor) was investigated. Numerical device simulator $ATLAS^{TM}$ was used to construct, examine, and simulate the structure in three dimensions with different models. The drain current, transconductance, threshold voltage, subthreshold swing, leakage current, drain induced barrier lowering, and on/off current ratio were studied in various biasing configurations. The temperature dependence of the main electrical parameters of a SOI TG n-FinFET was analyzed and discussed. Increased temperature led to degraded performance of some basic parameters such as subthreshold swing, transconductance, on-current, and leakage current. These results might be useful for further development of devises to strongly down-scale the manufacturing process.

• JSTS:Journal of Semiconductor Technology and Science
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• v.15 no.6
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• pp.585-593
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• 2015

In the nanoscale regime, many multigate devices are explored to reduce their size further and to enhance their performance. In this paper, design of a novel device called, Triple Material Surrounding Gate Tunnel Field effect transistor (TMSGTFET) has been developed and proposed. The advantages of surrounding gate and tunnel FET are combined to form a new structure. The gate material surrounding the device is replaced by three gate materials of different work functions in order to curb the short channel effects. A 2-D analytical modeling of the surface potential, lateral electric field, vertical electric field and drain current of the device is done, and the results are discussed. A step up potential profile is obtained which screens the drain potential, thus reducing the drain control over the channel. This results in appreciable diminishing of short channel effects and hot carrier effects. The proposed model also shows improved ON current. The excellent device characteristics predicted by the model are validated using TCAD simulation, thus ensuring the accuracy of our model.

• Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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• 2009.06a
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• pp.92-92
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• 2009

본 논문에서는 strained Silicon-on-Insulator (sSOI) 기판에 제작된 triple-gate MOSFETs 의 이동도와 단채널 효과에 대하여 분석 하였다. Strained 실리콘에 제작된 소자는 전류의 방향이 <110> 밤항일 경우 전자의 이동도는 증가하나 정공의 이동도는 오히려 감소하는 문제점이 있다. 이를 극복하기 위하여 소자에서 전류의 방향이 <110>방향에서 45 도 회전된 <100> 방향으로 흐르게 제작하였다. Strain이 가해지지 않은 기판에 제작된 동일한 구조의 소자와 비교하여 sSOI 에 제작된 소자에서 전자의 이동도는 약 40% 정공의 이동도는 약 50% 증가하였다. 채널 길이가 100 nm 내외로 감소함에 따라 나타나는 drain induced barrier lowering (DIBL) 현상, subthreshold slope (SS)의 증가 현상에서 sSOI에 제작된 소자가 상대적으로 우수한 특성을 보였으며 off-current leakage ($I_{off}$) 특성도 sSOI기판이 더 우수한 특성을 보였다.

• Proceedings of the Korean Vacuum Society Conference
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• 2010.02a
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• pp.248-248
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• 2010

CMOS 축소화가 32nm node를 넘어서 지속적으로 진행되기 위하여 FinFET, Surround Gate and Tri-Gate와 같은 Fully Depleted 3-Dimensional 소자들이 SCE를 다루기 위해서 많이 제안되어 왔다. 하지만 소자의 축소화를 진행함에 있어서 좁고 균일한 patterning을 형성하는 것과 동시에 낮은 Extension Region과 Contact Region에서의 Series Resistance을 제공하여야 하고 Source/Drain Contact Formation을 확보하여야 한다. 그리고 소자의 축소화가 진행됨으로써 Silicide의 응집현상과 Source/Drain Junction의 누설전류에 대한 허용범위가 점점 엄격해지고 있다. ITRS 2005에 따르면 32nm CMOS에서는 Contact Resistivity가 대략 $2{\times}10-8{\Omega}cm2$이 요구되고 있다. 또한 Three Dimensional 소자에서는 Fin Corner Effect가 Channel Region뿐만 아니라 S/D Region에서도 중대한 영향을 미치게 된다. 따라서 본 논문에서 제시하는 Novel S/D Contact Formation 기술을 이용하여 Self-Aligned Dual/Single Metal Contact을 이루어Patterning에 대한 문제점 해결과 축소화에 따라 증가하는 Contact Resistivity 문제점을 해결책을 제시하고자 한다. 이를 검증하기3D MOSFET제작하고 본 기술을 적용하고 검증한다. 또한 Normal Doping 구조를 가진3D MOSFET뿐만 아니라 SCE를 해결하기 위해서 대안으로 제시되고 있는 SB-MOSFET을 3D 구조로 제작하고, 이 기술을 적용하여 검증한다. 그리고 Silvaco simulation tool을 이용하여 S/D에 Metal이 Contact을 이루는 구조가 Double type과 Triple type에 따라 Contact Resistivity에 미치는 영향을 미리 확인하였고 이를 실험으로 검증하여 소자의 축소화에 따라 대두되는 문제점들의 해결책을 제시하고자 한다.

• Journal of the Institute of Electronics and Information Engineers
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• v.53 no.5
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• pp.69-76
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• 2016

Current driving capability of MCT (MOS Controlled Thyristor) is determined by turn-off capability of conducting current, that is off-FET performance of MCT. On the other hand, having a good turn-on characteristics, including high peak anode current ($I_{peak}$) and rate of change of current (di/dt), is essential for pulsed power system which is one of major application field of MCTs. To satisfy above two requirements, careful control of on/off-FET performance is required. However, triple diffusion and several oxidation processes change surface doping profile and make it hard to control threshold voltage ($V_{th}$) of on/off-FET. In this paper, we have demonstrated the effect of $V_{th}$ adjustment ion implantation on the performance of MCT. The fabricated MCTs (active area = $0.465mm^2$) show forward voltage drop ($V_F$) of 1.25 V at $100A/cm^2$ and Ipeak of 290 A and di/dt of $5.8kA/{\mu}s$ at $V_A=800V$. While these characteristics are unaltered by $V_{th}$ adjustment ion implantation, the turn-off gate voltage is reduced from -3.5 V to -1.6 V for conducting current of $100A/cm^2$ when the $V_{th}$ adjustment ion implantation is carried out. This demonstrates that the current driving capability is enhanced without degradation of forward conduction and turn-on switching characteristics.