Ciao‐Fen Chen scite author profile

Van der Waals (vdW) heterostructures-in which layered materials are purposely selected to assemble with each other-allow unusual properties and different phenomena to be combined and multifunctional electronics to be created, opening a new chapter for the spread of internet-of-things applications. Here, an O 2 -ultrasensitive MoTe 2 material and an O 2 -insensitive SnS 2 material are integrated to form a vdW heterostructure, allowing the realization of charge-polarity control for multioperation-mode transistors through a simple and effective rapid thermal annealing strategy under dry-air and vacuum conditions. The charge-polarity control (i.e., doping and de-doping processes), which arises owing to the interaction between O 2 adsorption/desorption and tellurium defects at the MoTe 2 surface, means that the MoTe 2 /SnS 2 heterostructure transistors can reversibly change between unipolar, ambipolar, and anti-ambipolar transfer characteristics. Based on the dynamic control of the charge-polarity properties, an inverter, output polarity controllable amplifier, p-n diode, and ternary-state logics (NMIN and NMAX gates) are demonstrated, which inspire the development of reversibly multifunctional devices and indicates the potential of 2D materials.

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Diffused Beam Energy to Dope van der Waals Electronics and Boost Their Contact Barrier Lowering

Lin

Lee

Chang

et al. 2022

ACS Appl. Mater. Interfaces

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Contact engineering of two-dimensional semiconductors is a central issue for performance improvement of micro-/nanodevices based on these materials. Unfortunately, the various methods proposed to improve the Schottky barrier height normally require the use of high temperatures, chemical dopants, or complex processes. This work demonstrates that diffused electron beam energy (DEBE) treatment can simultaneously reduce the Schottky barrier height and enable the direct writing of electrical circuitry on van der Waals semiconductors. The electron beam energy projected into the region outside the electrode diffuses into the main channel, producing selective-area n-type doping in a layered MoTe2 (or MoS2) field-effect transistor. As a result, the Schottky barrier height at the interface between the electrode and the DEBE-treated MoTe2 channel is as low as 12 meV. Additionally, because selective-area doping is possible, DEBE can allow the formation of both n- and p-type doped channels within the same atomic plane, which enables the creation of a nonvolatile and homogeneous MoTe2 p–n rectifier with an ideality factor of 1.1 and a rectification ratio of 1.3 × 103. These results indicate that the DEBE method is a simple, efficient, mask-free, and chemical dopant-free approach to selective-area doping for the development of van der Waals electronics with excellent device performances.

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Electrically Tunable Plasmonic Biosensors Based on Cavity-Coupled Structure With Graphene

Yang

Chung

Cheng

et al. 2021

IEEE J. Select. Topics Quantum Electron.

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Ciao‐Fen Chen

Reversible Charge‐Polarity Control for Multioperation‐Mode Transistors Based on van der Waals Heterostructures

Diffused Beam Energy to Dope van der Waals Electronics and Boost Their Contact Barrier Lowering

Electrically Tunable Plasmonic Biosensors Based on Cavity-Coupled Structure With Graphene

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