石墨烯以外二维材料的器件视角

14th IEEE International Conference on Nanotechnology Pub Date : 2014-12-01 DOI:10.1109/NANO.2014.6968159

P. Ye

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引用次数: 0

摘要

二维晶体的兴起给器件研究带来了新的挑战和机遇。半导体二硫化钼为n通道，磷烯为p通道，被认为是未来微电子和光电子器件中有前途的超薄体通道。在本文中，我们关注的是这些二维晶体管的基本器件特性。第一部分介绍了原子层沉积在二硫化钼和其他二维晶体上的介电集成，揭示了块体晶体和二维晶体上介电集成的异同。然后，我们展示了MoS2上不同的金属接触，在金属/二维界面上显示费米水平钉住。通过分子化学掺杂，可以将MoS2的接触电阻降低到0.5 Ω·mm，并证明了漏极电流为460 mA/mm的高性能MoS2 fet。然后讨论了MoS2晶体管沟道长度和宽度的缩放问题。最后，我们展示了一个具有MoS2 fet和几层磷烯fet的二维CMOS逆变器，展示了这些二维晶体上异质器件集成的潜力。

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Device perspective of 2D materials beyond graphene

The rise of two-dimensional (2D) crystals has given new challenges and opportunities to the device research. The semiconducting MoS2 as n-channel and few-layer phosphorene as p-channel have been considered as promising ultra-thin body channels for future microelectronic and optoelectronic devices. In this paper, we focus on the fundamental device properties in these 2D transistors. In the first part we introduce the dielectric integration on MoS2 and other 2D crystals by atomic layer deposition, revealing the similarities and differences of dielectric integration on bulk and 2D crystals. Then we present the different metal contacts on MoS2, showing Fermi level pinning at metal/2D interfaces. Through molecular chemical doping, contact resistance to MoS2 is able to be reduced to 0.5 Ω·mm and high-performance MoS2 FETs with drain current of 460 mA/mm are demonstrated. Then we discuss scaling of channel length and width of MoS2 transistors. Finally we demonstrate a 2D CMOS inverter with a MoS2 NFET and a few-layer phosphorene PFET, showing the potentials on these 2D crystals for heterogeneous device integrations.

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14th IEEE International Conference on Nanotechnology

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