首页> 外文会议>2010 IEEE International Electron Devices Meeting >Non-planar, multi-gate InGaAs quantum well field effect transistors with high-K gate dielectric and ultra-scaled gate-to-drain/gate-to-source separation for low power logic applications

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Non-planar, multi-gate InGaAs quantum well field effect transistors with high-K gate dielectric and ultra-scaled gate-to-drain/gate-to-source separation for low power logic applications

机译：非平面，多栅极InGaAs量子阱场效应晶体管，具有高K栅极电介质和超规模的栅-漏/栅-源隔离，适用于低功耗逻辑应用

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In this work, non-planar, multi-gate InGaAs quantum well field effect transistors (QWFETs) with high-K gate dielectric and ultra-scaled gate-to-drain and gate-to-source separations (LSIDE) of 5nm are reported for the first time. The high-K gate dielectric formed on this non-planar device structure has the expected thin TOXE of 20.5Å with low JG, and high quality gate dielectric interface. The simplified S/D scheme is needed for the non-planar architecture while achieving significant reduction in parasitic resistance. Compared to the planar high-K InGaAs QWFET with similar TOXE, the non-planar, multi-gate InGaAs QWFET shows significantly improved electrostatics due to better gate control. The results of this work show that non-planar, multi-gate device architecture is an effective way to improve the scalability of III–V QWFETs for low power logic applications.

机译：在这项工作中，非平面，多栅极InGaAs量子阱场效应晶体管（QWFET）具有高K栅极介电层和超大规模的栅极到漏极和栅极到源极的间距（L SIDE ）。在这种非平面器件结构上形成的高K栅极电介质具有20.5Å的预期薄TOXE和低J G 以及高质量的栅极电介质界面。非平面架构需要简化的S / D方案，同时要显着降低寄生电阻。与具有相似的T OXE 的平面高K InGaAs QWFET相比，非平面多栅极InGaAs QWFET由于更好的栅极控制而显示出显着改善的静电。这项工作的结果表明，非平面，多栅极器件架构是提高III-V QWFET在低功耗逻辑应用中可扩展性的有效方法。

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《2010 IEEE International Electron Devices Meeting》|2010年|p.1-4|共4页
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入库时间 2022-08-26 15:08:50

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Non-planar, multi-gate InGaAs quantum well field effect transistors with high-K gate dielectric and ultra-scaled gate-to-drain/gate-to-source separation for low power logic applications

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