Your search keyword '"Xiang-Wei Jiang"' showing total 2 results

1. Gate-controlled reversible rectifying behaviour in tunnel contacted atomically-thin MoS2 transistor.

Author

Xiao-Xi Li, Mao-Lin Chen, Dong-Ming Sun, Zheng Han, Zhi-Dong Zhang, Zhi-Qiang Fan, Xiang-Wei Jiang, Pei-Zhi Liu, Jun-Jie Guo, Xin Liu, Jian-Hao Chen, Chuan-Kun Jia, and Bouchiat, Vincent

Subjects

SEMICONDUCTORS, BAND gaps, NANOELECTRONICS, FIELD-effect transistors, GRAPHENE

Abstract

Atomically thin two-dimensional semiconducting materials integrated into van der Waals heterostructures have enabled architectures that hold great promise for next generation nanoelectronics. However, challenges still remain to enable their applications as compliant materials for integration in logic devices. Here, we devise a reverted stacking technique to intercalate a wrinkle-free boron nitride tunnel layer between MoS2 channel and source drain electrodes. Vertical tunnelling of electrons therefore makes it possible to suppress the Schottky barriers and Fermi level pinning, leading to homogeneous gate-control of the channel chemical potential across the bandgap edges. The observed features of ambipolar pn to np diode, which can be reversibly gate tuned, paves the way for future logic applications and high performance switches based on atomically thin semiconducting channel. [ABSTRACT FROM AUTHOR]

Published

2017

2. Performance limits of tunnel transistors based on mono-layer transition-metal dichalcogenides.

Author

Xiang-Wei Jiang and Shu-Shen Li

Subjects

*FIELD-effect transistors, *CHALCOGENIDES, *PERFORMANCE evaluation, *QUANTUM tunneling, *DIELECTRIC properties, *STRAINS & stresses (Mechanics)

Abstract

Performance limits of tunnel field-effect transistors based on mono-layer transition metal dichalcogenides are investigated through numerical quantum mechanical simulations. The atomic mono-layer nature of the devices results in a much smaller natural length λ, leading to much larger electric field inside the tunneling diodes. As a result, the inter-band tunneling currents are found to be very high as long as ultra-thin high-k gate dielectric is possible. The highest on-state driving current is found to be close to 600 μA/μm at Vg=Vd=0.5V when 2 nm thin HfO2 layer is used for gate dielectric, outperforming most of the conventional semiconductor tunnel transistors. In the five simulated transition-metal dichalcogenides, mono-layer WSe2 based tunnel field-effect transistor shows the best potential. Deep analysis reveals that there is plenty room to further enhance the device performance by either geometry, alloy, or strain engineering on these mono-layer materials. [ABSTRACT FROM AUTHOR]

Published

2014