A novel contact engineering method for transistors based on two-dimensional materials

doi:10.1016/j.jmst.2020.05.079

Abstract

Abstract:

Contact engineering is of critical importance for two-dimensional (2D) transition metal dichalcogenide (TMD)-based devices. However, there are only a few solutions to overcome this obstacle because of the complexity of the TMD-contact interface. In this work, we propose a novel method using a soft plasma treatment followed by the seamless deposition of a metal electrode to reduce the contact resistance of MoS₂ field effect transistors (FETs). The treated FETs exhibit three times higher mobility than the control FETs without plasma treatment. The soft plasma treatment can remove the facial sulfur atoms and expose the middle Mo atoms so that they come into direct contact with the metal electrode, thus greatly improving the contact behavior. First-principles calculation is also performed to support the experimental results. Our potentially scalable strategy can be extended to the whole family of TMD based FETs to provide a possible route of device processsing technology for 2D device application.

Key words: Electrical contact resistance, MoS₂, Plasma

Yaochen Sheng, LuFang Zhang, Feng Li, Xinyu Chen, Zhijian Xie, Haiyan Nan, Zihan Xu, David Wei Zhang, Jianhao Chen, Yong Pu, Shaoqing Xiao, Wenzhong Bao. A novel contact engineering method for transistors based on two-dimensional materials[J]. J. Mater. Sci. Technol., 2021, 69: 15-19.

Figures/Tables 3

Fig. 1. Schematic diagram of the device fabrication. (a) illustrates the device processing sequence and (b) a 3D cartoon of the modified UHV chamber. Firstly, S/D electrode regions are defined by lithography and exposed after developing, then the semi-finished device is placed into the UHV chamber, which consists of a planar ICP and a magnetron sputtering system. After plasma treatment and subsequent deposition of metal electrodes, the device is taken out of the chamber and completed by removing the sacrificial photoresist.

Fig. 2. (a) IDS-VBG transfer characteristics of mechanically exfoliated MoS2 FETs subjected to H2 plasma with different treatment times and input powers. 3-4 layer MoS2 flakes were chosen for fabricating these devices. (b) Corresponding statistical mobility values of the devices with treatment recipes shown in (a). IDS-VBG transfer characteristics of CVD-synthesized monolayer MoS2 based FETs (c) without and (d) with H2 plasma treatment (100 W, 30 min). Drain-source bias is 1 V for all devices.

Fig. 3. (a) Top view of crystal structures of pristine and modified 1 L MoS2 nanosheet with top S atoms at both ends are etched by plasma. (b) The three-dimensional diagram of MoS2 FET with plasma treatment. (c) Charge densities of the valence band maximum and conduction band minimum of the MoS-MoS2-MoS nanosheet. The iso-value is 0.003 e ?-3. (d) Electronic band structure of pristine and modified monolayer MoS2 nanosheet. The Fermi energy Ef is set at 0 eV in the dashed line.

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