Assembly of Silver Nanoparticles into Hollow Spheres Using Eu(III) Compound based on Trifluorothenoyl-Acetone

The preparation of luminescent silver hollow spheres using Eu(III) compound based on trifluorothenoyl-acetone is described. The structure and size of silver hollow spheres were determined by TEM images. The result shows the formation of hollow structure and average size of the silver hollow spheres (0.9 μm). The silver hollow spheres were further characterized by UV absorption spectrum, SNOM and SEM images, suggesting them to be formed by self-assemble of some isolated silver nanoparticles. The luminescent properties of them were also investigated and they are shown to be high emission strength; moreover, they offer the distinct advantage of a lower packing density compared with other commercial luminescent products

Sandwich-like layer-by-layer assembly of gold nanoparticles with tunable SERS properties

Sandwich-like layer-by-layer thin films consisting of polyelectrolytes and gold nanoparticles were utilized to construct surface-enhanced Raman scattering (SERS) substrates with tunable SERS properties. It is found that both the size of the nanoparticles in the layers and the interlayer distance significantly influence the SERS performance of the multilayered thin film. These simple, low-cost, easily processable and controllable SERS substrates have a promising future in the field of molecular sensing

Mechanical and tribological properties of basalt fiber fabric reinforced polyamide 6 composite laminates with interfacial enhancement by electrostatic self-assembly of graphene oxide

Exploring simple, efficient and applicable interfacial optimisation methods is important to enhance the overall performance of basalt fibre (BF) fabric-reinforced thermoplastic composite laminates. Graphene oxide (GO) was introduced on the surface of BF fabric through electrostatic self-assembly to improve the interfacial bonding of BF fabric-reinforced polyamide 6 (PA6) composites laminates (BF/PA6) for enhancing the mechanical and frictional wear properties of the composites. It was concluded that surface electrostatic assembly of GO resulted in a significant increase in surface roughness, wettability, surface energy and surface chemical activity of BF fabrics without damaging the fibre backbone structure. With the GO concentration of 0.8 g/L, the interlaminar shear strength, impact strength, flexural strength and flexural modulus of the BF/PA6 composites were increased by 85.1 %, 43.2 %, 53.2 % and 63.4 %, and the average friction coefficient and wear rate was reduced by 15.2 % and 40.5 %, respectively. The introduced homogeneous GO strengthens the interfacial bonding of such fibre-fabric reinforced thermoplastic composites by creating mechanical engagement, similar compatibility and chemical cross-linking between the BF fabrics and the PA6 matrix. With enhanced interfacial bonding, the BF fabric reinforced thermoplastic composites possess enhanced stress damage resistance. Under frictional reciprocating stress, the introduced GO inhibited the generation and expansion of microcracks, formed frictional transfer film to play solid lubrication and anti-wear role, and enhanced the thermal stability of the composites to mitigate the frictional thermal damage. The interfacial enhancement method of BF fabric-reinforced thermoplastic composites provided in this study is simple, green, efficient and has good potential for application

Controllable molecular configuration for significant improvement of blue OLEDs based on novel twisted anthracene derivatives

Two novel twisted anthracene derivatives, 2-(4-(10-(phenanthren-9-yflanthracen-9-yl)phenyl)-1-phenyl-1H-phenanthro[9,10-d]-imidazole (p-PABPI) and 2-(3-(10-(phenan-thren-9-yl)anthracen-9-yl)phenyl)-1-phenyl-1H-phenanthro-[9,10-d]imidazole (m-PABPI), have been synthesized. Their photophysical and photochemical properties are also investigated systemically. The non-doped fluorescent organic light-emitting diodes are fabricated by using anthracene derivatives as the emitters. The maximum current efficiencies are achieved to be 3.98 and 132 cd A(-1) and the maximum power efficiencies are 2.80 and 1.14 Im W-1, respectively. The external quantum efficiency maximum (EQEmax) is 3.61% and 1.33% for p-PABPI and m-PABPI. Intriguingly, the efficiencies of p-PABPI are almost three times larger than that of m-PABPI with only the different molecular configuration. The results revealed a new rule of molecular design based on anthracene derivatives for obtaining high performance blue emission materials. (C) 2015 Elsevier Ltd. All rights reserved

Granular, Slow-Release Fertilizer from Urea-formaldehyde, Ammonium Polyphosphate, and Amorphous Silica Gel: A New Strategy Using Cold Extrusion

A new granular, slow-release fertilizer prepared by a cold-extrusion strategy (GSRFEx) based on urea-formaldehyde (UF), ammonium polyphosphate (APP), and amorphous silica gel (ASG) was presented. Characterizations showed that there were strong hydrogen-bond interactions and good compatibility among UF, APP, and ASG in GSRFEx. The mechanical properties as well as the slow-release properties of GSRFEx were greatly enhanced after the addition of APP and ASG to UF. Rape pot experiments indicated that GSRFEx could improve N-use efficiency dramatically and thereby facilitate the growth of rape. Importantly, as an economical, effective, and environment-friendly technology, cold extrusion has great potential to be applied in horticulture and agriculture. We hope that our work can offer an alternative method for the design of slow-release fertilizers with desirable properties