• Title/Summary/Keyword: Silicon nanowire transistor

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Breakdown Characteristics of Silicon Nanowire N-channel GAA MOSFET (실리콘 나노와이어 N-채널 GAA MOSFET의 항복특성)

  • Ryu, In Sang;Kim, Bo Mi;Lee, Ye Lin;Park, Jong Tae
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.20 no.9
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    • pp.1771-1777
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    • 2016
  • In this thesis, the breakdown voltage characteristics of silicon nanowire N-channel GAA MOSFETs were analyzed through experiments and 3-dimensional device simulation. GAA MOSFETs with the gate length of 250nm, the gate dielectrics thickness of 6nm and the channel width ranged from 400nm to 3.2um were used. The breakdown voltage was decreased with increasing gate voltage but it was increased at high gate voltage. The decrease of breakdown voltage with increasing channel width is believed due to the increased current gain of parasitic transistor, which was resulted from the increased potential in channel center through floating body effects. When the positive charge was trapped into the gate dielectrics after gate stress, the breakdown voltage was decreased due to the increased potential in channel center. When the negative charge was trapped into the gate dielectrics after gate stress, the breakdown voltage was increased due to the decreased potential in channel center. We confirmed that the measurement results were agreed with the device simulation results.

Temperature Effect on the Interface Trap in Silicon Nanowire Pseudo-MOSFETs

  • Nam, In-Cheol;Kim, Dae-Won;Heo, Geun;Najam, Syed Faraz;Hwang, Jong-Seung;Hwang, Seong-U
    • Proceedings of the Korean Vacuum Society Conference
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    • 2013.02a
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    • pp.487-487
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    • 2013
  • According to shrinkage of transistor, interface traps have been recognized as a major factor which limits the process development in manufacturing industry. The traps occur through spontaneous generation process, and spread into the forbidden band. There is a large change of current though a few traps are existed at the Si-SiO2 interface. Moreover, the increased temperature largely affects to the leakage current due to the interface trap. For this reason, we made an effort to find out the relationship between temperature and interface trap. The subthreshold swing (SS) was investigated to confirm the correlation. The simulated results show that the sphere of influence of trap is enlarged according to increase in temperature. To investigate the relationship between thermal energy and surface potential, we extracted the average surface potential and thermal energy (kT) according to the temperature. Despite an error rate of 6.5%, change rates of both thermal energy and average surface potential resemble each other in many ways. This allows that SS is affected by the trap within the range of the thermal energy from the surface energy.

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NANOCAD Framework for Simulation of Quantum Effects in Nanoscale MOSFET Devices

  • Jin, Seong-Hoon;Park, Chan-Hyeong;Chung, In-Young;Park, Young-June;Min, Hong-Shick
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.6 no.1
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    • pp.1-9
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    • 2006
  • We introduce our in-house program, NANOCAD, for the modeling and simulation of carrier transport in nanoscale MOSFET devices including quantum-mechanical effects, which implements two kinds of modeling approaches: the top-down approach based on the macroscopic quantum correction model and the bottom-up approach based on the microscopic non-equilibrium Green’s function formalism. We briefly review these two approaches and show their applications to the nanoscale bulk MOSFET device and silicon nanowire transistor, respectively.

Fabrication of wrap-around gate nanostructures from electrochemical deposition (전기화학적 도금을 이용한 wrap-around 게이트 나노구조의 제작)

  • Ahn, Jae-Hyun;Hong, Su-Heon;Kang, Myung-Gil;Hwang, Sung-Woo
    • Journal of IKEEE
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    • v.13 no.2
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    • pp.126-131
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    • 2009
  • To overcome short channel effects, wrap-around field effect transistors have drawn a great deal of attention for their superior electrostatic coupling between the channel and the surrounding gate electrode. In this paper, we introduce a bottom-up technique to fabricate a wrap-around field effect transistor using silicon nanowires as the conduction channel. Device fabrication was consisted mainly of electron-beam lithography, dielectrophoresis to accurately align the nanowires, and the formation of gate electrode using electrochemical deposition. The electrolyte for electrochemical deposition was made up of non-toxic organic-based solution and liquid nitrogen was used as a method of maintaining the shape of polymethyl methacrylate(PMMA) during the process of electrochemical deposition. Patterned PMMA can be used as a nano-template to produce wrap-around gate nano-structures.

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