• Title/Summary/Keyword: SOI FinFET

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Dynamic Self-Heating Effects of Bulk and SOI FinFET with Realistic Device Structure (실제적 구조를 가진 벌크 및 SOI FinFET에서 발생하는 동적 self-heating 효과)

  • Ryu, Heesang;Chung, Hayun Cecillia;Yang, Ji-Woon
    • Journal of the Institute of Electronics and Information Engineers
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    • v.52 no.10
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    • pp.64-69
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    • 2015
  • Self-heating effects of bulk and SOI FinFETs on device structure are examined with TCAD simulation. The degradation of drive current in SOI FinFET is severer than that of bulk one in steady-state condition as expected. However, it is shown that the dynamic self-heating effects of SOI FinFETs are comparable to those of bulk FinFETs for high speed logic operation, especially in realistic device structure.

Trend and issues of the bulk FinFET (벌크 FinFET의 기술 동향 및 이슈)

  • Lee, Jong-Ho;Choi, Kyu-Bong
    • Vacuum Magazine
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    • v.3 no.1
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    • pp.16-21
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    • 2016
  • FinFETs are able to be scaled down to 22 nm and beyond while suppressing effectively short channel effect, and have superior performance compared to 2-dimensional (2-D) MOSFETs. Bulk FinFETs are built on bulk Si wafers which have less defect density and lower cost than SOI(Silicon-On-Insulator) wafers. In contrast to SOI FinFETs, bulk FinFETs have no floating body effect and better heat transfer rate to the substrate while keeping nearly the same scalability. The bulk FinFET has been developed at 14 nm technology node, and applied in mass production of AP and CPU since 2015. In the development of the bulk FinFETs at 10 nm and beyond, self-heating effects (SHE) is becoming important. Accurate control of device geometry and threshold voltage between devices is also important. The random telegraph noise (RTN) would be problematic in scaled FinFET which has narrow fin width and small fin height.

유전체 물질을 삽입한 N-channel FinFETs의 전기적 특성

  • An, Jun-Seong;Kim, Tae-Hwan
    • Proceedings of the Korean Vacuum Society Conference
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    • 2014.02a
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    • pp.301.2-301.2
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    • 2014
  • 집적회로의 밀도가 높이기 위해 단일 소자의 크기를 줄이는 과정에서 발생하는 소자의 성능 저하를 줄이기 위해 새로운 구조 및 구성 물질을 변경하는 연구가 활발하게 진행되고 있다. 기존의 평면 구조를 변형한 3차원 구조의 n-channel FinFet는 소자의 구성 물질을 바꾸지 않고도 쇼트 채널효과와 누설전류를 줄일 수 있다. 다양한 구조의 유전 물질을 응용한 n-channel FinFEET은 기존의 n-channel FinFET보다 소자의 크기를 줄일 수 있는 가능성을 제시하고 있다. FinFETs에 관한 많은 연구가 진행되어 왔지만, 유전체 물질을 이용한 n-channel FinFETs의 구조에 대한 연구는 매우 적다. 본 연구는 FinFET의fin channel 영역에 유전 물질을 삽입하여 그 영향을 분석한 연구이다. FinFET의 fin channel 영역에 유전 물질을 삽입하여 평면 구조의 MOSFET에서 fully depletion SOI 구조와 같은 동작을 하도록 만들었다. 유전 물질을 삽입한 FinFET 소자의 전기적 특성을 3차원 TCAD 시뮬레이션을 툴을 이용하여 계산하였다. 유전 물질을 삽입한 n-channel FinFET에서 전자 밀도와 측면 전계의 영향이 기존의 FinFET보다 좋은 특성을 확인하였다. 또한 유전물질을 삽입한 FinFETs은 subthershold swing, 누설전류, 소비전력을 줄여 주었다. 이러한 결과는 n-Channel FinFETs의 성능을 향상시키는데 많은 도움이 될 것이다.

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Non-Quasi-Static RF Model for SOI FinFET and Its Verification

  • Kang, In-Man
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.10 no.2
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    • pp.160-164
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    • 2010
  • The radio frequency (RF) model of SOI FinFETs with gate length of 40 nm is verified by using a 3-dimensional (3-D) device simulator. This paper shows the equivalent circuit model which can be used in the circuit analysis simulator. The RMS modeling error of Y-parameter was calculated to be only 0.3 %.

Fabrication of SOI FinFET devices using Aresnic solid-phase-diffusion (비소 고상확산방법을 이용한 MOSFET SOI FinFET 소자 제작)

  • Cho, Won-Ju;Koo, Hyun-Mo;Lee, Woo-Hyun;Koo, Sang-Mo;Chung, Hong-Bay
    • Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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    • 2006.11a
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    • pp.133-134
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    • 2006
  • A simple doping method to fabricate a very thin channel body of the n-type fin field-effect-transistor (FinFET) with a 20 nm gate length by solid-phase-diffusion (SPD) process is presented. Using As-doped spin-on-glass as a diffusion source of arsenic and the rapid thermal annealing, the n-type source-drain extensions with a three-dimensional structure of the FinFET devices were doped. The junction properties of arsenic doped regions were investigated by using the $n^+$-p junction diodes which showed excellent electrical characteristics. Single channel and multi-channel n-type FinFET devices with a gate length of 20-100 nm was fabricated by As-SPD and revealed superior device scalability.

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Impacts of Trapezoidal Fin of 20-nm Double-Gate FinFET on the Electrical Characteristics of Circuits

  • Ryu, Myunghwan;Kim, Youngmin
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.15 no.4
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    • pp.462-470
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    • 2015
  • In this study, we analyze the impacts of the trapezoidal fin shape of a double-gate FinFET on the electrical characteristics of circuits. The trapezoidal nature of a fin body is generated by varying the angle of the sidewall of the FinFET. A technology computer-aided-design (TCAD) simulation shows that the on-state current increases, and the capacitance becomes larger, as the bottom fin width increases. Several circuit performance metrics for both digital and analog circuits, such as the fan-out 4 (FO4) delay, ring oscillator (RO) frequency, and cut-off frequency, are evaluated with mixed-mode simulations using the 3D TCAD tool. The trapezoidal nature of the FinFET results in different effects on the driving current and gate capacitance. As a result, the propagation delay of an inverter decreases as the angle increases because of the higher on-current, and the FO4 speed and RO frequency increase as the angle increases but decrease for wider angles because of the higher impact on the capacitance rather than the driving strength. Finally, the simulation reveals that the trapezoidal angle range from $10^{\circ}$ to $20^{\circ}$ is a good tradeoff between larger on-current and higher capacitance for an optimum trapezoidal FinFET shape.

Impact of Fin Aspect Ratio on Short-Channel Control and Drivability of Multiple-Gate SOI MOSFET's

  • Omura, Yasuhisa;Konishi, Hideki;Yoshimoto, Kazuhisa
    • 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.

Temperature Dependence of Electrical Parameters of Silicon-on-Insulator Triple Gate n-Channel Fin Field Effect Transistor

  • Boukortt, Nour El Islam;Hadri, Baghdad;Caddemi, Alina;Crupi, Giovanni;Patane, Salvatore
    • 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.

3-D Simulation of Nanoscale SOI n-FinFET at a Gate Length of 8 nm Using ATLAS SILVACO

  • Boukortt, Nour El Islam;Hadri, Baghdad;Caddemi, Alina;Crupi, Giovanni;Patane, Salvatore
    • Transactions on Electrical and Electronic Materials
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    • v.16 no.3
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    • pp.156-161
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    • 2015
  • In this paper, we present simulation results obtained using SILVACO TCAD tools for a 3-D silicon on insulator (SOI) n-FinFET structure with a gate length of 8 nm at 300K. The effects of variations of the device’s key electrical parameters, such as threshold voltage, subthreshold slope, transconductance, drain induced barrier lowering, oncurrent, leakage current and on/off current ratio are presented and analyzed. We will also describe some simulation results related to the influence of the gate work function variations on the considered structure. These variations have a direct impact on the electrical device characteristics. The results show that the threshold voltage decreases when we reduce the gate metal work function Φm. As a consequence, the behavior of the leakage current improves with increased Φm. Therefore, the short channel effects in real 3-D FinFET structures can reasonably be controlled and improved by proper adjustment of the gate metal work function.

Feasibility Study of Non-volatile Memory Device Structure for Nanometer MOSFET (나노미터 MOSFET비휘발성 메모리 소자 구조의 탐색)

  • Jeong, Ju Young
    • Journal of the Semiconductor & Display Technology
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    • v.14 no.2
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    • pp.41-45
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    • 2015
  • From 20nm technology node, the finFET has become standard device for ULSI's. However, the finFET process made stacking gate non-volatile memory obsolete. Some reported capacitor-less DRAM structure by utilizing the FBE. We present possible non-volatile memory device structure similar to the dual gate MOSFET. One of the gates is left floating. Since body of the finFET is only 40nm thick, control gate bias can make electron tunneling through the floating gate oxide which sits across the body. For programming, gate is biased to accumulation mode with few volts. Simulation results show that the programming electron current flows at the interface between floating gate oxide and the body. It also shows that the magnitude of the programming current can be easily controlled by the drain voltage. Injected electrons at the floating gate act similar to the body bias which changes the threshold voltage of the device.