# Giant Enhancement of Solid Solubility in Monolayer BNC Alloys by   Selective Orbital Coupling

**Authors:** Shiqiao Du, Jianfeng Wang, Lei Kang, Bing Huang, and Wenhui Duan

arXiv: 1907.12847 · 2020-02-12

## TL;DR

This paper introduces a novel substrate-mediated orbital coupling mechanism that dramatically enhances the solid solubility of monolayer BNC alloys, enabling tunable electronic and optical properties for advanced optoelectronic applications.

## Contribution

It proposes a new substrate-driven orbital coupling approach to significantly increase the solid solubility of BNC alloys across all compositions.

## Key findings

- Formation of five ordered alloys with tunable bandgaps on Cr substrate.
- Disordered alloys with fully tunable bandgaps from 0 to ~6 eV.
- Reduced miscibility temperature for alloy formation on Cr substrate.

## Abstract

Solid solubility (SS) is one of the most important features of alloys, which is usually difficult to be largely tuned in the entire alloy concentrations by external approaches. Some alloys that were supposed to have promising physical properties could turn out to be much less useful because of their poor SS, e.g., the case for monolayer BNC [(BN)1-x(C2)x] alloys. Until now, an effective approach on significantly enhancing SS of (BN)1-x(C2)x in the entire x is still lacking. In this article, a novel mechanism of selective orbital coupling between high energy wrong-bond states and surface states mediated by the specific substrate has been proposed to stabilize the wrong-bonds and in turn significantly enhance the SS of (BN)1-x(C2)x alloys. Surprisingly, we demonstrate that five ordered alloys, exhibiting variable direct quasi-particle bandgaps from 1.35 to 3.99 eV, can spontaneously be formed at different x when (BN)1-x(C2)x is grown on hcp-phase Cr. Interestingly, the optical transitions around the band edges in these ordered alloys, accompanied by largely tunable exciton binding energies of ~1 eV at different x, are significantly strong due to their unique band structures. Importantly, the disordered (BN)1-x(C2)x alloys, exhibiting fully tunable bandgaps from 0 to ~6 eV in the entire x, can be formed on Cr substrate at the miscibility temperature of ~1200 K, which is greatly reduced compared to that of 4500~5600 K in free-standing form or on other substrates. Our discovery not only may resolve the long-standing SS problem of BNC alloys, but also could significantly extend the applications of BNC alloys for various optoelectronic applications.

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Source: https://tomesphere.com/paper/1907.12847