Sheng Meng scite author profile

Honeycomb structures of group IV elements can host massless Dirac fermions with non-trivial Berry phases. Their potential for electronic applications has attracted great interest and spurred a broad search for new Dirac materials especially in monolayer structures. We present a detailed investigation of the β12 boron sheet, which is a borophene structure that can form spontaneously on a Ag(111) surface. Our tight-binding analysis revealed that the lattice of the β12-sheet could be decomposed into two triangular sublattices in a way similar to that for a honeycomb lattice, thereby hosting Dirac cones. Furthermore, each Dirac cone could be split by introducing periodic perturbations representing overlayer-substrate interactions. These unusual electronic structures were confirmed by angle-resolved photoemission spectroscopy and validated by first-principles calculations. Our results suggest monolayer boron as a new platform for realizing novel high-speed low-dissipation devices.

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The effect of a layer-by-layer chitosan–heparin coating on the endothelialization and coagulation properties of a coronary stent system

Meng

et al. 2009

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Robust Stacking-Independent Ultrafast Charge Transfer in MoS₂/WS₂ Bilayers

et al. 2017

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Van der Waals-coupled two-dimensional (2D) heterostructures have attracted great attention recently due to their high potential in the next-generation photodetectors and solar cells. The understanding of charge-transfer process between adjacent atomic layers is the key to design optimal devices as it directly determines the fundamental response speed and photon-electron conversion efficiency. However, general belief and theoretical studies have shown that the charge transfer behavior depends sensitively on interlayer configurations, which is difficult to control accurately, bringing great uncertainties in device designing. Here we investigate the ultrafast dynamics of interlayer charge transfer in a prototype heterostructure, the MoS/WS bilayer with various stacking configurations, by optical two-color ultrafast pump-probe spectroscopy. Surprisingly, we found that the charge transfer is robust against varying interlayer twist angles and interlayer coupling strength, in time scale of ∼90 fs. Our observation, together with atomic-resolved transmission electron characterization and time-dependent density functional theory simulations, reveals that the robust ultrafast charge transfer is attributed to the heterogeneous interlayer stretching/sliding, which provides additional channels for efficient charge transfer previously unknown. Our results elucidate the origin of transfer rate robustness against interlayer stacking configurations in optical devices based on 2D heterostructures, facilitating their applications in ultrafast and high-efficient optoelectronic and photovoltaic devices in the near future.

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Sheng Meng

Dirac Fermions in Borophene

The effect of a layer-by-layer chitosan–heparin coating on the endothelialization and coagulation properties of a coronary stent system

Robust Stacking-Independent Ultrafast Charge Transfer in MoS₂/WS₂ Bilayers

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Sheng Meng

Dirac Fermions in Borophene

The effect of a layer-by-layer chitosan–heparin coating on the endothelialization and coagulation properties of a coronary stent system

Robust Stacking-Independent Ultrafast Charge Transfer in MoS2/WS2 Bilayers

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Robust Stacking-Independent Ultrafast Charge Transfer in MoS₂/WS₂ Bilayers