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Field-effect at electrical contacts to two-dimensional materials

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arxiv 2101.09487 v1 pith:X2NNHE3E submitted 2021-01-23 physics.app-ph

Field-effect at electrical contacts to two-dimensional materials

classification physics.app-ph
keywords electricalcontactsfield-effectmaterialscircuitscontactabilitycritical
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The inferior electrical contact to two-dimensional (2D) materials is a critical challenge for their application in post-silicon very large-scale integrated circuits. Electrical contacts were generally related to their resistive effect, quantified as contact resistance. With a systematic investigation, this work demonstrates a capacitive metal-insulator-semiconductor (MIS) field-effect at the electrical contacts to 2D materials: the field-effect depletes or accumulates charge carriers, redistributes the voltage potential, and give rise to abnormal current saturation and nonlinearity. On the one hand, the current saturation hinders the devices' driving ability, which can be eliminated with carefully engineered contact configurations. On the other hand, by introducing the nonlinearity to monolithic analog artificial neural network circuits, the circuits' perception ability can be significantly enhanced, as evidenced using a COVID-19 critical illness prediction model. This work provides a comprehension of the field-effect at the electrical contacts to 2D materials, which is fundamental to the design, simulation, and fabrication of electronics based on 2D material.

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