AI Article Synopsis
- Two-dimensional boron materials have garnered attention for their unique structures and impressive properties, yet they have not been successfully synthesized until now.
- A new method, involving chemical vapor deposition on copper foils with boron and boron oxide, has successfully created atomically thin 2D γ-boron films.
- The resulting boron film displays an optical band gap of 2.25 eV, similar to theoretical predictions, and exhibits strong photoluminescence, indicating potential applications in electronic and photonic devices.
Article Abstract
Two-dimensional boron materials have recently attracted extensive theoretical interest because of their exceptional structural complexity and remarkable physical and chemical properties. However, such 2D boron monolayers have still not been synthesized. In this report, the synthesis of atomically thin 2D γ-boron films on copper foils is achieved by chemical vapor deposition using a mixture of pure boron and boron oxide powders as the boron source and hydrogen gas as the carrier gas. Strikingly, the optical band gap of the boron film was measured to be around 2.25 eV, which is close to the value (2.07 eV) determined by first-principles calculations, suggesting that the γ-B28 monolayer is a fascinating direct band gap semiconductor. Furthermore, a strong photoluminescence emission band was observed at approximately 626 nm, which is again due to the direct band gap. This study could pave the way for applications of two-dimensional boron materials in electronic and photonic devices.
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| http://dx.doi.org/10.1002/anie.201509285 | DOI Listing |
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