Zero-Dipole Schottky Contact: Homologous Metal Contact to 2D Semiconductor

Abstract

Band alignment of metal contacts to 2D semiconductors often deviate from the ideal Shottky-Mott (SM) rule due to the non-ideal factors such as the formation of interface dipole and metal-induced gap states (MIGS). Although MIGS can be strongly suppressed using van der Waals (vdW) contact engineering, the interface dipole is hard to eliminate due to the electronegativity difference of the two contacting materials. Here we show that interface dipole can be practically eliminated in 2D semiconducting MoSi2N4 when contacted by its homologous metallic counterpart MoSi2N4(MoN)n (n = 1-4). The SiN outer sublayers, simultaneously present in both MoSi2N4 and MoSi2N4(MoN)n, creates nearly equal charge `push-back' effect at the contact interface. This nearly symmetrical charge redistribution leads to zero net electron transfer across the interface, resulting in a zero-dipole contact. Intriguingly, we show that even in the extreme close-contact case where MoSi2N4(MoN) is arbitrarily pushed towards MoSi2N4 with extremely small interlayer distance, the interface dipole remains practically zero. Such zero-dipole Schottky contact represents a peculiar case where the SM rule, usually expected to occur only in the non-interacting regime, manifests in MoSi2N4/MoSi2N4(MoN)n vdWH even though the constituent monolayers interact strongly. A model for pressure sensing is then proposed based on changing the interlayer distance in MoSi2N4/MoSi2N4(MoN) vdWH.

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