In0.7Ga0.3As多栅极量子阱场效应管(MuQFET)的可扩展性和输运实验研究

69th Device Research Conference Pub Date : 2011-06-20 DOI:10.1109/DRC.2011.5994401

L. Liu, V. Saripalli, V. Narayanan, S. Datta

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引用次数: 1

摘要

化合物半导体，如In0.7Ga0.3As和InSb，由于其优越的传输特性，正在积极研究作为硅通道材料在逻辑应用中的替代品[1,2]。在低电源电压(Vcc)应用中，平面III-V量子阱场效应管已经证明比最先进的Si mosfet具有更好的性能[1-3]。一个关键的研究挑战仍然是解决基于III-V的量子阱场效应管在14纳米以下节点逻辑应用中的可扩展性，同时仍然保持其出色的传输优势。在本研究中，我们展示了非平面、多栅极、调制掺杂、应变的In0.7Ga0.3As量子阱场效应管(MuQFET)的准弹道运行，结合了多栅极结构的静电鲁棒性和高迁移率量子阱通道In0.7Ga0.3As的优异电子迁移率(图1)。

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Experimental investigation of scalability and transport in In0.7Ga0.3As multi-gate quantum well FET (MuQFET)

Compound semiconductors such as In0.7Ga0.3As and InSb are being actively researched as replacement for silicon channel materials for logic applications due to their superior transport properties [1,2]. Planar III–V quantum-well FETs have already demonstrated with superior performance than the state-of-the art Si MOSFETs for low supply voltage (Vcc) applications [1–3]. A key research challenge remains in addressing the scalability of III-V based quantum-well FETs to sub-14 nm node logic applications while still maintaining their excellent transport advantage. In this study, we demonstrate quasi-ballistic operation of non-planar, multi-gate, modulation doped, strained In0.7Ga0.3As quantum well FET (MuQFET), combining the electrostatic robustness of multi-gate configuration with the excellent electron mobility of high mobility quantum well channel, In0.7Ga0.3As (Figure 1).

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69th Device Research Conference

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