Emerging Two-Dimensional Tellurene and Tellurides for Broadband Photodetectors.

As with all stylish 2D functional materials, tellurene and tellurides possessing excellent physical and chemical properties such as high environmental stability, tunable narrow bandgap, and lower thermal conductivity, have aroused the great interest of the researchers. These properties of such materials also form the basis for relatively newfangled scholarly fields involving advanced topics, especially for broadband photodetectors. Integrating the excellent properties of many 2D materials, tellurene/telluride-based photodetectors show great flexibility, higher frequency response or faster time response, high signal-to-noise ratio, and so on, which make them leading the frontier of photodetector research. To fully understand the excellent properties of tellurene/tellurides and their optoelectronic applications, the recent advances in tellurene/telluride-based photodetectors are maximally summarized. Benefiting from the solid research in this field, the challenges and opportunities of tellurene/tellurides for future optoelectronic applications are also discussed in this review, which might provide possibilities for the realization of state-of-the-art high-performance tellurene/telluride-based devices.

Anti-Inflammatory Mechanism of Ligustrum Lucidum Ait Based on Network Pharmacology and Molecular Docking.

OBJECTIVE: To investigate possible targets of Ligustrum lucidum and its anti-inflammatory mechanism. Core targets were screened by the established networks of component target and potential protein interaction, accompanied by GO and KEGG analyses. The findings were confirmed using molecular docking. RESULTS: eight active components including Quercetin, luteolin, kaempferol and corresponding 163 potential targets, including CCL2, IL6, CXCL8, TNF, IL1B, were identified with a threshold of OB ≥ 30% and DL ≥ 0.18%. 1018 anti-inflammatory targets were acquired, with 101 common targets identified by mutual mapping. 172 nodes and 287 edges are readable in the "component target" visualization network graph. The KEGG analysis identified 20 significantly differentiated signaling pathways, including IL-17, toll-like receptor, TNF, HIF-1, lipid and atherosclerosis. CONCLUSION: Molecular docking has verified the binding sites and energies of the chemical components in Ligustrum lucidum with key anti-inflammatory proteins, providing a theoretical basis for its clinical use and development.

Remarkably enhanced dynamic oxygen migration on graphene oxide supported by copper substrate.

The dynamic covalent properties of graphene oxide (GO) are of fundamental interest to a broad range of scientific areas and technological applications. It remains a challenge to access feasible dynamic reactions for reversibly breaking/reforming the covalent bonds of oxygen functional groups on GO, although these reactions can be induced by photonic or mechanical routes, or mediated by adsorbed water. Here, using density functional theory calculations, we demonstrate the remarkably enhanced dynamic oxygen migration along the basal plane of GO supported by copper substrate (GO@copper), with C-O bond breaking reactions and proton transfer between neighboring epoxy and hydroxyl groups. Compared to reactions on GO, the energy barriers of oxygen migrations on GO@copper are sharply reduced to be less than or comparable to thermal fluctuations, and meanwhile the crystallographic match between GO and copper substrate induces new oxygen migration paths on GO@copper. This work sheds light on understanding of the metal substrate-enhanced dynamic properties of GO, and evidences the strategy to tune the activity of two-dimensional-interfacial oxygen groups for various potential applications.