Fabrication and Characterization of Self-Aligned WSe2 p-Type Field-Effect Transistor

Abstract

Semiconducting transition metal dichalcogenides (TMDCs) have been growing interests as channel materials in field effect transistors (FET) for next generation low power digital electronics. [1]. Since a complementary metal oxide-semiconductor (CMOS) inverter constructed from pairs of n-type and p-type FETs is a fundamental building blocks in modern digital electronics [2], implementation of both n-type and p-type FETs with semiconducting TMDCs is of particular importance [3]. Among various semiconducting TMDCs, tungsten diselenide (WSe2) is a promising candidate for constructing a CMOS inverter because of its high mobility, symmetric electron and hole effective mass and ambipolar transport [4]. These prominent features of WSe2 is suitable for an application to CMOS inverter.One of the significant challenges is to develop a top gate and top contact FET structure with WSe2 for CMOS device integration on the same wafer. In addition, it is desirable to minimize the access region between channel and S/D contact because this access region served as a series resistance to channel resistance, resulting in the lower drain current in FET. This study reports a self-aligned process to fabricate top gate and top contact WSe2 p-type FET. In this self-aligned structure, the gate electrode and source/drain contact edges are automatically positioned and hence there are no overlap or access region between the gate and source/drain. The feature of this proposed method is that the gate stacks was utilized as a mask for self-aligned formation of WOx, which is source/drain contact for efficient hole injection [5]. The focus on this study is the impact of self-aligned structure of p-type WSe2 FET on the electrical characteristics. The effectiveness of proposed process was experimentally demonstrated by the fabrication and characterization of device.Figures 1 shows the self-aligned fabrication process of p-type WSe2 FET. 20 nm-thick SiO2 was formed by dry oxidation of p+-Si substrate. The mechanically exfoliated multi-layer WSe2 was transferred by PDMS stamp. Next, 15 nm-thick Al2O3 was prepared by ALD at 200 oC with H2O. Then, Nickel (Ni) metal was deposited by RF sputtering on Al2O3. Ni metal was patterned for gate electrode with conventional lithography process. After that, A2O3 layer was removed by wet etching. Subsequently, substrate was exposed to oxygen radicals to form WOx used as source/drain contact at surface of WSe2. Second layer of Al2O3 was deposited as an encapsulating passivation layer. After the contact hole opening, the electrical contact pad was fabricated. Finally, forming gas (N2 : H2 = 97 % : 3 %) annealing was performed at 200 oC for 30 min. The top gate length was 5 μm. The gate width was estimated to be 40 μm by optical microscope. The electrical characteristics were measured with a manual probe station in an atmospheric pressure without inert gas purge at room temperature using a precision semiconductor parameter analyzer (Agilent 4156 C).Figures 2 shows the Id–Vg characteristics of fabricated FETs for (a) back gate operation and (b) top gate operation. Representative Id–Vg characteristics of p-type FETs were observed irrespective of back gate and top gate operation. The on/off ratio of about 106 ~ 107 order were obtained for both back gate and top gate operation. Furthermore, the threshold voltage and sub-threshold slope were modulated by varying the substrate bias during gate sweep.This study opens up interesting directions for the research and development of TMDC-based devices.AcknowledgmentsThis study was supported by a JSPS Grant-in-Aid for Scientific Research (C) (Grant No. 20K04616), a research grant for Tokyo Tech Challenging Research Award, the Samco Foundation and a research grant for Suematsu Award.