A flexible and stable biomimetic SERS substrate was successfully fabricated by depositing gold (Au) nanoislands on the dragonfly wings (DW) via a simple DC magnetron sputtering system. Characterizations of the Au/DW nanostructure indicated that the optimum Au/DW-45 (sputtering time was 45 min) substrate owns high sensitivity, good stability and outstanding reproducibility. The limit of detection (LOD) for Rhodamine 6 G (R6G) was as low as 10−7 M and enhancement factor (EF) was calculated to be 2.8 × 106. 70-day-duration stability tests showed that Raman intensity of R6G reduced only by 12.9% after aging for 70 days. The maximum relative standard deviations (RSD) of SERS intensities from 100 positions of Au/DW-45 substrate were less than 8.3%, revealing outstanding uniformity and reproducibility. Moreover, the flexible Au/DW-45 bioscaffold arrays were employed to solve the vital problem of pesticide residues. By directly sampling from tomato peels via a “press and peel off” approach, cypermethrin has been rapidly and reliably determined with a LOD centered at 10−3 ng/cm2 and a correlation coefficient (R2) of 0.987. The positive results demonstrated that the Au-based DW biomimetic arrays may offer an efficient SERS platform for the identification of various pesticide residues on real samples.
A series of zeolite X/activated carbon (AC) composites were prepared from the same starting materials at various activation time. The corresponding modified samples were obtained by being treated with diluted NH4Cl solution. The relationship between porosity development, surface properties, and CH4/N2 adsorption performance was investigated. The increase of micropore volume is beneficial to the improvement of CH4 and N2 adsorption capacity, but more sensitive for CH4. In addition, the polar functional groups of zeolite X/AC composites may enhance CH4 adsorption capacity. More importantly, both developing micropore structure and surface modification contributed to enhance the adsorption selectivity αCH4/N2. As the optimum sample of these studies, HZAC(24) showed CH4 adsorption capacity of 17.3 cm3/g and the highest adsorption selectivity αCH4/N2 of 3.4. The CH4 and N2 adsorption isotherms of all samples can be well fitted by the Langmuir–Freundlich model. HZAC(24) showed an excellent cyclability of adsorption/desorption of CH4 with a neglectable capacity loss after subsequent cycles. Moreover, HZAC(24) displayed relatively rapid adsorption kinetics. These properties of zeolite X/AC composites are essential for the adsorptive separation of CH4 from N2 in the pressure swing adsorption (PSA) process.
Arc brazing technology for joining has been recently developed. Because of its
advantages, it has been used more and more frequently in the automobile industry, and this
technology is widely used in practical joining applications. Many welding researchers have paid
more and more attentions in this field. Based on the experimental analysis of CuSi3 filler metal
spreading, wetting behavior on galvanized steel sheet and its interfacial microstructure in tungsten
inert gas (TIG) arc brazing process, the governing equations and boundary conditions of filler metal
droplets under the actions of gravitational force, surface tension and arc pressure force is conducted,
then they have been transformed into finite volume equations, The flow behavior at different arcing
time in filler metal droplet was calculated by PHOENICS code using SIMPLEST algorithm. It can
be concluded that the flow adjacent to the surface controls the final droplet profile, and the fluid
flow does great contribution to the whisker-like intermetallic compound fragmentation behavior due
to its stirring force at the interface. The simulation is useful to interpret the free surface evolving
behavior and the final profile of filler metal droplet in arc brazing, it also provide a new idea about
the interface growth behavior study and offer a practical guide in production.
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