Unveiling the singular symmetry in facet-engineered 2D materials growth

In a crystal, facets refer to the planes composed of different atom arrangements. In nature, crystals tend to form a polyhedral shape as a result of multi-facets, and realizing single-facet in a crystal is very challenging. Nonetheless, in a study published in the KeAi journal Advanced Powder Materials, a group of researchers from China outlined a new synthesis approach that can synthesize large-area 2D materials with atomic thickness and expose single-facet at the same time.

"The exposed facet is crucial since it determines the surface structure and property of 2D materials," explains first author of the study Jingwei Wang, Shuimu Scholar at Shenzhen International Graduate School, Tsinghua University. "Previously, most researchers used wet-chemistry methods to synthesize nanoparticles with specific facets. However, these samples suffer from small surface area, low quality, and the presence of multiple facets which is not suitable for studying the identical properties of one certain facet.”

The study's multidisciplinary team of scientists found that using a three-fold symmetric growth substrate, such as mica, yields 2D MnSe crystals with a (111) facet. Conversely, on a two-fold symmetric substrate like MgO (100), 2D MnSe crystals with (100) facets can be grown. These 2D MnSe flakes not only exhibit large-area surfaces of single-facet but also possess high crystallinity and ordered domain orientation. They further prove that these samples are ideal candidates for studying facet-dependent properties (e.g. electrocatalysis).

"Until now, revealing the relationship between crystal facet and properties is challenging since the nanomaterials usually expose multi-facets. Our approach shows that the single-facet can be controlled in atomic thin 2D materials on specific growth substrates." says Bilu Liu, the corresponding author of the study."We hope that our results encourage scientists to continue investigating facet-engineering of 2D materials for desired properties and applications."

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Contact the author: Bilu Liu, Shenzhen Geim Graphene Center, Tsinghua-Berkeley Shenzhen Institute and Institute of Materials Research, Shenzhen International Graduate School, Tsinghua University, Shenzhen, 518055, P. R. China bilu.liu@sz.tsinghua.edu.cn

The publisher KeAi was established by Elsevier and China Science Publishing & Media Ltd to unfold quality research globally. In 2013, our focus shifted to open access publishing. We now proudly publish more than 100 world-class, open access, English language journals, spanning all scientific disciplines. Many of these are titles we publish in partnership with prestigious societies and academic institutions, such as the National Natural Science Foundation of China (NSFC).