The effects of processing parameters on formation of nano-spinel (MgAl2O4) from LiCl moltensalt

Nano-MgAl₂O₄ particles were successfully synthesized at 850 °C using the molten-salt method, and the effects of processing parameters, such as temperature, holding time and amount of salt on the crystallization of MgAl₂O₄ were investigated. Nano-alumina, magnesia and lithium chloride were used as starting materials. LiCl molten salt provided a liquid medium for reaction of Al₂O₃ and MgO to form MgAl₂O₄. The results demonstrated that MgAl₂O₄ started to form at about 650 °C and that, after the temperature was increased to 1000 °C, the amounts of MgAl₂O₄ in the resultant powders increased with a concomitant decrease in Al₂O₃ and MgO contents. After washing with hot-distilled water, the samples heated for 3 h at 850 °C were single-phase MgAl₂O₄ with 30–50 nm particle size. Furthermore, the synthesized MgAl₂O₄ particles retained the size and morphology of the Al₂O₃ powders, which indicated that a template formation mechanism dominated the formation of MgAl₂O₄ by molten-salt method.     

纳米材料在国内外油气田开发中的应用进展

从油气田开发对新技术、新产品的需求出发，从以下七个方面（钻探、采注、调剖、钻井液，污水处理、防腐、润滑）探讨了油气田开发领域存在的技术问题和应用纳米技术和材料的可能性和优势性，为今后纳米技术在油气田开发中的应用提供了新思路。     

Zein and zein -based nano-materials for food and nutrition applications: A review

BackgroundZein, a byproduct of corn with renewable resources, unique hydrophobic/hydrophilic character, film/fiber forming and antioxidant properties, is a promising biopolymer for food and nutrition applications. The advantages in properties and efficiencies of nano materials over bulk counterparts are the basis of their unique nature in novel technologies. These advantages also expand their possible applications.Scope and approachAn effort has been made to review on applications of zein/zein-based nano-materials in various branches of food (except food packaging) and nutrition sectors. The effects of various parameters affecting preparations and properties of the nano-materials are also discussed. Nano-encapsulation of foods and nutrients is the major section of this study.Key findings and conclusions(i) the average size of zein nanoparticles reported to be 50–200 nm; (ii) the functions of zein nanomaterials were multiples: a carrier of delivery (food, beverage, and nutrient) systems; a shell or a core of encapsulated systems; or a food ingredient; (iii) zein-based nano-materials have been used for encapsulation of food and nutrient components including lipids; essential oils; fat soluble vitamins; food colorants; flavors; and natural anti-oxidants; (iv) the bioavailability of food and nutrient components such as folic acid, vitamin D₃, curcumin, beta-carotene, and resveratrol was improved by employing the zein-nanoparticles in comparison with the bulk counterparts; and (v) bioactive substances with potential applications for food and nutrition sectors were stabilized by zein/zein-based nano-materials.     

纳米SnO2包覆TiO2光催化剂的制备及光催化活性研究

利用均匀沉淀法制备了纳米SnO2包覆TiO2的光催化剂，通过XRD、紫外光谱、色谱-质谱和光催化氧化焦化废水实验，分析和检验了该光催化剂的光催化活性。结果表明：SnO2包覆TiO2对光催化活性的提高是可行的，SnO2包覆量大于5％时提高效果较明显。     

摩擦喷射纳米Al2O3/Ni复合镀层的组织形貌及其性能研究

采用摩擦喷射电沉积工艺制备了纳米Al2O3／Ni复合镀层，考察了该镀层的表面和断面形貌，并对镀层性能进行了测试分析。研究表明，摩擦喷射纳米Al2O3／Ni复合镀层表面较为平整，镀层与基体结合紧密。一次性镀覆厚度达到1．40mm，远高于电刷镀纳米Al2O3／Ni复合镀层（0．35mm），镀层硬度达到650HV。在试验条件下，该镀层的耐磨性是摩擦喷射Ni镀层的1．44倍，是纳米Al2O3／Ni刷镀层的1．15倍，摩擦因数也低于摩擦喷射Ni镀层和电刷镀纳米Al2O3／Ni复合镀层。     

Preparation of Sn–3.5Ag nano-solder by supernatant process

The nano-scaled Sn–3.5Ag solder was prepared successfully by a supernatant process in the present study. The morphology of the nano-particle was investigated by scanning electron microscopy (SEM) and transmission electron microscopy (TEM), respectively. It was found from the SEM micrographs that the average diameter of the particle was 137 nm with a standard deviation of ±5 nm. From the TEM studies it was revealed that the particles aggregated into larger particles and the shape of the elongated particles were irregular. The composition of the alloy was also measured by an electron probe microanalyzer (EPMA) and energy dispersive spectroscopy (EDS), qualitatively and quantitatively. The eutectic element, Ag with a weight percentage of 3.5%, was found to be homogenous over all of the particles. Furthermore, the microstructure of the Sn–3.5Ag alloy was identified by X-ray diffraction. It was found that the trace element, Ag was dissolved in the matrix, a tetragonal system, without an intermetallic phase.     

Effect of ZnO doping on morphology and electrochemical properties of sub-micron RuO2 sensing electrode of DO sensor

Thick-film 20 mol% ZnO-doped RuO₂ sensing electrodes (SEs) were fabricated by screen-printing technique on the platinised alumina substrate of the planar electrochemical dissolved oxygen (DO) sensor. The effect of ZnO doping on morphology, electrochemical properties and sensing characteristics of the sensor was investigated. It was found that ZnO doping has not only improved the SE structure, but has also enhanced selectivity of the DO sensor. Selectivity testing exhibited that the presence of Cl⁻, Li⁺, SO₄²⁻, NO³⁻, Ca²⁺, PO₄³⁻, Mg²⁺, Na⁺ and K⁺ with a concentration range of 10⁻⁷ to 10⁻¹ mol/L in the solution had practically no effect on the sensor's emf. The reason in enhancement of the sensor characteristics could be related to the establishment of the better structured SE as more advanced crystallization is achieved for the doped RuO₂-SE.     

Corrosion resistance enhancement of Ni–P electroless coatings by incorporation of nano-SiO2 particles

Composite coatings were prepared using hypophosphite reduced electroless nickel bath containing 7 g/L SiO₂ nano-particles at pH 4.6 ± 0.2 and temperature 90 ± 2 °C. Deposition rate for SiO₂ nano-composite coatings was 10–12 μm/h. The amount of SiO₂ nano-particles co-deposited in the Ni–P matrix was around 2 wt.%. The analyzes of coating compositions, carried out by Energy Dispersive Analysis of X-ray (EDAX), showed that plain Ni–P and Ni–P/nano-SiO₂ deposits contained around 8 wt.% phosphorus. The X-ray diffraction (XRD) pattern of Ni–P/nano-SiO₂ coating was very similar to that of plain electroless Ni–P coating, whose structure was also amorphous.     

Synthesis and characterization of titanium-45S5 Bioglass nanocomposites

Titanium-45S5 Bioglass nanocomposites were synthesized by the combination of mechanical alloying and powder metallurgy process. The structure, mechanical and corrosion properties of these materials were investigated. Microhardness test showed that the obtained material exhibits Vicker’s microhardness as high as 770 HV_0.2 for Ti-20 wt.% 45S5 Bioglass, which is more than three times higher than that of a conventional microcrystalline titanium (225 HV_0.2). Additionally, titanium-10 wt.% of 45S5 Bioglass nanocomposites (i_c = 1.20 × 10⁻⁷ A/cm², E_c = −0.42 V vs. SCE) were more corrosion resistant than microcrystalline titanium (i_c = 2.27 × 10⁻⁶ A/cm², E_c = −0.36 V vs. SCE). In vitro biocompatibility of these materials was evaluated and compared with a conventional microcrystalline titanium, where normal human osteoblast (NHOst) cells from Cambrex (CC-2538) were cultured on the disks of the materials and cell growth was examined. The morphology of the cell cultures obtained on Ti-10 wt.% 45S5 Bioglass nanocomposite was similar to those obtained on the microcrystalline titanium. Mechanical alloying and powder metallurgy process for the fabrication of titanium-45S5 Bioglass nanocomposites with a unique microstructure, higher hardness, lower Young’s modulus and better corrosion resistance, in comparison to microcrystalline titanium, were developed. On the other hand, Ti-10 wt.% 45S5 Bioglass composites posses higher fracture toughness compared to 45S5 Bioglass. The proper modification of chemical composition and microstructure of Ti-bioceramic nanocomposites can expand the use of titanium in the biomedical fields.     

Tetrapod-like nano-particle ZnO/acrylic resin composite and its multi-function property

Tetrapod-like nano-particle ZnO/acrylic resin composite was prepared by a direct dispersing method forming a multi-function coating. The composite with uniform distribution of nano-ZnO in the acrylic resin have both anti-electrostatic and antibacterial functions. The coatings can be used for plastic materials or others. The mechanisms of the electrostatic and antibacterial functions were also analyzed.