Semiconductor Quantum Dots as Photocatalysts for Controlled Light-Mediated Radical Polymerization

Light-mediated radical polymerization has benefited from the rapid development of photoredox catalysts and offers many exceptional advantages over traditional thermal polymerizations. Nevertheless, the majority of the work relies on molecular photoredox catalysts or expensive transition metals. We exploited the capability of semiconductor quantum dots (QD) as a new type of catalyst for the radical polymerization that can harness natural sunlight. Polymerizations of (meth)­acrylates, styrene, and construction of block copolymers were demonstrated, together with temporal control of the polymerization by the light source. Photoluminescence experiments revealed that the reduction of alkyl bromide initiator by photoexcited QD is the key to this light-mediated radical polymerization

Direct Formation of Electronic Excited NO₂ Contributes to the High Yield of HONO during Photosensitized Renoxification

Photosensitized renoxification of HNO3 is found to produce HONO in an unexpectedly high yield, which has been considered an important source for atmospheric HONO. Conventionally, the production of HONO is ascribed to the secondary photolysis of the primarily formed NO2. In this study, by using humic acid (HA) as a model environmental photosensitizer, we provide evidence of the direct formation of NO2 in its electronic excited state (NO2*) as a key intermediate during the photosensitizing renoxification of HNO3. Moreover, the high HONO yield originates from the heterogeneous reaction of the primarily formed NO2* with the co-adsorbed water molecules on HA. Such a mechanism is supported by the increase of the product selectivity of HONO with relative humidity. Further luminescence measurements demonstrate clearly the occurrence of an electronic excited state (NO2*) from photolysis of adsorbed HNO3 on HA. This work deepens our understanding of the formation of atmospheric HONO and gives insight into the transformation of RNS

Strain Tuning Self-Assembled Quantum Dots for Energy-Tunable Entangled-Photon Sources Using a Photolithographically Fabricated Microelectromechanical System

Self-assembled quantum dots (QDs) offer versatile sources of quantum light for photonic quantum technologies thanks to their atomic-like discrete energy levels for deterministic generation of single photons. Though, the unavoidable inhomogeneous broadening and the ubiquitous presence of the fine structure splitting (FSS) of the exciton states hamper their use as high-fidelity entangled-photon sources (EPSs) with well-defined energies, core elements in scalable networking quantum applications. To overcome these challenges, in this work, we propose and demonstrate a photolithographically fabricated microelectromechanical system (MEMS) to dynamically control the optical properties of QDs. The device features two orthogonal and independent uniaxial stresses that can tune the exciton energy and the FSS simultaneously, enabling demonstration of energy-tunable EPSs based on self-assembled QDs. The device can be processed by only employing standard photolithography techniques, which alleviates the use of sophisticated device design and fabrications, thus providing a viable route toward the realization of entanglement swapping with all-solid-state quantum emitters

IKKε Knockout Prevents High Fat Diet Induced Arterial Atherosclerosis and NF-κB Signaling in Mice

<div><p>Aims</p><p>Atherosclerosis is a public health concern affecting many worldwide, but its pathogenesis remains unclear. In this study we investigated the role of IKKε during the formation of atherosclerosis and its molecular mechanism in the mouse aortic vessel wall.</p><p>Methods and Results</p><p>C57BL/6 wild-type or IKKε knockout mice bred into the ApoE knockout genetic background were divided into 4 groups: (1) wild-type (WT), (2) ApoE knockout (AK), (3) IKKε knockout (IK), (4) or both ApoE and IKKε knockout (DK). Each group of mice were fed with a high fat diet (HFD) for 12 weeks from 8 weeks of age. Immunohistochemistry and Western blotting analysis demonstrated obvious increases in the expression of IKKε in the AK group compared with the WT group, especially in the intima. Serum lipid levels were significantly higher in the AK and DK groups than in the other two groups. Staining with hematoxylin-eosin and Oil Red, as well as scanning electron microscopy revealed less severe atherosclerotic lesions in the DK group than in the AK group. Immunofluorescence and Western blot analysis demonstrated obvious increases in the expression of NF-κB pathway components and downstream factors in the AK group, especially in the intima, while these increases were blocked in the DK group.</p><p>Conclusion</p><p>The knockout of IKKε prevented significant atherosclerosis lesions in the mouse aorta from in both wild-type and ApoE knockout mice fed a HFD, suggesting that IKKε may play a vital role in HFD-induced atherosclerosis and would be an important target for the treatment of atherosclerosis.</p></div

Selective Cleavage of α‑Olefins to Produce Acetylene and Hydrogen

Acetylene production from mixed α-olefins emerges as a potentially green and energy-efficient approach with significant scientific value in the selective cleavage of C–C bonds. On the Pd(100) surface, it is experimentally revealed that C2 to C4 α-olefins undergo selective thermal cleavage to form surface acetylene and hydrogen. The high selectivity toward acetylene is attributed to the 4-fold hollow sites which are adept at severing the terminal double bonds in α-olefins to produce acetylene. A challenge arises, however, because acetylene tends to stay at the Pd(100) surface. By using the surface alloying methodology with alien Au, the surface Pd d-band center has been successfully shifted away from the Fermi level to release surface-generated acetylene from α-olefins as a gaseous product. Our study actually provides a technological strategy to economically produce acetylene and hydrogen from α-olefins

Discovery of Selective P2Y₆R Antagonists with High Affinity and <i>In Vivo</i> Efficacy for Inflammatory Disease Therapy

As a member of purinoceptors, the P2Y6 receptor (P2Y6R) plays a crucial role in modulating immune signals and has been considered as a potential therapeutic target for inflammatory diseases. On the basis of the speculated probable conformation and binding determinants of P2Y6R, a hierarchical strategy that combines virtual screening, bioassays, and chemical optimization was presented. A potent P2Y6R antagonist (compound 50) was identified to possess excellent antagonistic activity (IC50 = 5.914 nM) and high selectivity. In addition, binding assays and chemical pull-down experiments confirmed that compound 50 was nicely bound to P2Y6R. Notably, compound 50 could effectively ameliorate DSS-induced ulcerative colitis in mice through inhibiting the activation of NLRP3 inflammasome in colon tissues. Moreover, treatment with compound 50 reduced LPS-induced pulmonary edema and infiltration of inflammatory cells in mice. These findings suggest that compound 50 could serve as a specific P2Y6R antagonist for treating inflammatory diseases and deserve further optimization studies

Discovery of Selective P2Y₆R Antagonists with High Affinity and <i>In Vivo</i> Efficacy for Inflammatory Disease Therapy

As a member of purinoceptors, the P2Y6 receptor (P2Y6R) plays a crucial role in modulating immune signals and has been considered as a potential therapeutic target for inflammatory diseases. On the basis of the speculated probable conformation and binding determinants of P2Y6R, a hierarchical strategy that combines virtual screening, bioassays, and chemical optimization was presented. A potent P2Y6R antagonist (compound 50) was identified to possess excellent antagonistic activity (IC50 = 5.914 nM) and high selectivity. In addition, binding assays and chemical pull-down experiments confirmed that compound 50 was nicely bound to P2Y6R. Notably, compound 50 could effectively ameliorate DSS-induced ulcerative colitis in mice through inhibiting the activation of NLRP3 inflammasome in colon tissues. Moreover, treatment with compound 50 reduced LPS-induced pulmonary edema and infiltration of inflammatory cells in mice. These findings suggest that compound 50 could serve as a specific P2Y6R antagonist for treating inflammatory diseases and deserve further optimization studies

Discovery of Selective P2Y₆R Antagonists with High Affinity and <i>In Vivo</i> Efficacy for Inflammatory Disease Therapy

As a member of purinoceptors, the P2Y6 receptor (P2Y6R) plays a crucial role in modulating immune signals and has been considered as a potential therapeutic target for inflammatory diseases. On the basis of the speculated probable conformation and binding determinants of P2Y6R, a hierarchical strategy that combines virtual screening, bioassays, and chemical optimization was presented. A potent P2Y6R antagonist (compound 50) was identified to possess excellent antagonistic activity (IC50 = 5.914 nM) and high selectivity. In addition, binding assays and chemical pull-down experiments confirmed that compound 50 was nicely bound to P2Y6R. Notably, compound 50 could effectively ameliorate DSS-induced ulcerative colitis in mice through inhibiting the activation of NLRP3 inflammasome in colon tissues. Moreover, treatment with compound 50 reduced LPS-induced pulmonary edema and infiltration of inflammatory cells in mice. These findings suggest that compound 50 could serve as a specific P2Y6R antagonist for treating inflammatory diseases and deserve further optimization studies

A General Synthesis Method for Covalent Organic Framework and Inorganic 2D Materials Hybrids

Two-dimensional (2D) inorganic/organic hybrids provide a versatile platform for diverse applications, including electronic, catalysis, and energy storage devices. The recent surge in 2D covalent organic frameworks (COFs) has introduced an organic counterpart for the development of advanced 2D organic/inorganic hybrids with improved electronic coupling, charge separation, and carrier mobility. However, existing synthesis methods have primarily focused on few-layered film structures, which limits scalability for practical applications. Herein, we present a general synthesis approach for a range of COF/inorganic 2D material hybrids, utilizing 2D inorganic materials as both catalysts and inorganic building blocks. By leveraging the intrinsic Lewis acid sites on the inorganic 2D materials such as hexagonal boron nitride (hBN) and transition metal dichalcogenides, COFs with diverse functional groups and topologies can grow on the surface of inorganic 2D materials. The controlled 2D morphology and excellent solution dispersibility of the resulting hybrids allow for easy processing into films through vacuum filtration. As proof of concept, hBN/COF films were employed as filters for Rhodamine 6G removal under flow-through conditions, achieving a removal rate exceeding 93%. The present work provides a simple and versatile synthesis method for the scalable fabrication of COF/inorganic 2D hybrids, offering exciting opportunities for practical applications such as water treatment and energy storage

Spin-Phonon Coupling in Iron-Doped Ultrathin Bismuth Halide Perovskite Derivatives

Spin in semiconductors facilitates magnetically controlled optoelectronic and spintronic devices. In metal halide perovskites (MHPs), doping magnetic ions is proven to be a simple and efficient approach to introducing a spin magnetic momentum. In this work, we present a facile metal ion doping protocol through the vapor-phase metal halide insertion reaction to the chemical vapor deposition (CVD)-grown ultrathin Cs3BiBr6 perovskites. The Fe-doped bismuth halide (Fe:CBBr) perovskites demonstrate that the iron spins are successfully incorporated into the lattice, as revealed by the spin-phonon coupling below the critical temperature Tc around 50 K observed through temperature-dependent Raman spectroscopy. Furthermore, the phonons exhibit significant softening under an applied magnetic field, possibly originating from magnetostriction and spin exchange interaction. The spin-phonon coupling in Fe:CBBr potentially provides an efficient way to tune the spin and lattice parameters for halide perovskite-based spintronics