Preparation and electrochemical characterization of Ti-based amorphous metallic glass with high strength

Ti-based amorphous metallic glasses have excellent mechanical, physical, and chemical properties, which is an important development direction and research hotspot of metal composite reinforcement. As a stable, simple, efficient, and large-scale preparation technology of metallic powders, the gas atomization process provides an effective way of preparing amorphous metallic glasses. In this study, the controllable fabrication of a Ti-based amorphous powder, with high efficiency, has been realized by using gas atomization. The scanning electron microscope, energy-dispersive spectrometer, and X-ray diffraction are used to analyze surface morphology, element distribution, and phase structure, respectively. A microhardness tester is used to measure the mechanical property. An electrochemical workstation is used to characterize corrosion behavior. The results show that as-prepared microparticles are more uniform and exhibit good amorphous characteristics. The mechanical test shows that the hardness of amorphous powder is significantly increased as compared with that before preparation, which has the prospect of being an important part of engineering reinforced materials. Further electrochemical measurement shows that the corrosion resistance of the as-prepared sample is also significantly improved. This study has laid a solid foundation for expanding applications of Ti-based metallic glasses, especially in heavy-duty and corrosive domains.     

Effect of MnOx phase on Pt-based catalyst for enhancing CO/C3H6/NO oxidation performance

To improve the fuel economy, it is crucial to promote the low-temperature performance in eliminating diesel emissions. The work investigates the impact of different MnO₂/Mn₂O₃ phase ratio on the low-temperature performance of Pt-based monolithic diesel oxidation catalyst. Near equal ratio of MnO_x phase could form the three-phase (platinum, MnO₂, Mn₂O₃) interfacial structure, leading to the smaller platinum particle size and exhibiting the higher interface rate (1.6–11.1 times) than other mono-manganese oxide with platinum. Besides, the higher oxygen mobility and more active oxygen species could be contributed to the positive effect of Pt/MnO_x interface, which are prevalent to activate the reactant and greatly enhance the TOF value (1.4–20.8 times). The results imply that the modification of multi-phase metal/oxide interface is potential in dispersing platinum for greatly enhancing the catalytic efficiency.     

Facile construction of composition-tuned ruthenium-nickel nanoparticles on g-C3N4 for enhanced hydrolysis of ammonia borane without base additives

Developing high-efficiency and low-cost catalysts for hydrogen evolution from hydrolysis of ammonia borane (AB) is significant and critical for the exploitation and utilization of hydrogen energy. Herein, the in-situ fabrication of well-dispersed and small bimetallic RuNi alloy nanoparticles (NPs) with tuned compositions and concomitant hydrolysis of AB are successfully achieved by using graphitic carbon nitride (g-C₃N₄) as a NP support without additional stabilizing ligands. The optimized Ru₁Ni_7.5/g-C₃N₄ catalyst exhibits an excellent catalytic activity with a high turnover frequency of 901 min^?1 and an activation energy of 28.46 kJ mol^?1 without any base additives, overtaking the activities of many previously reported catalysts for AB hydrolysis. The kinetic studies indicate that the AB hydrolysis over Ru₁Ni_7.5/g-C₃N₄ is first-order and zero-order reactions with respect to the catalyst and AB concentrations, respectively. Ru₁Ni_7.5/g-C₃N₄ has a good recyclability with 46% of the initial catalytic activity retained even after five runs. The high performance of Ru₁Ni_7.5/g-C₃N₄ should be assigned to the small-sized alloy NPs with abundant accessible active sites and the synergistic effect between the composition-tuned Ru–Ni bimetals. This work highlights a potentially powerful and simple strategy for preparing highly active bimetallic alloy catalysts for AB hydrolysis to generate hydrogen.     

伊利石和高岭石对U(Ⅵ)的吸附

以伊利石和高岭石为吸附剂，通过静态吸附法研究了其对U(Ⅵ)的吸附特性。考察了接触时间、初始浓度、吸附剂质量、pH、温度、离子种类、腐殖酸等对其吸附效果的影响；采用红外光谱(FTIR) 对伊利石和高岭石的结构进行了表征。研究结果表明：伊利石和高岭石对U(Ⅵ)具有很强的吸附能力，在10 h、铀初始质量浓度为30 mg/L、吸附剂质量为0.04 g、pH=5的条件下，伊利石对U(Ⅵ)的吸附效果最好；在12 h、铀初始质量浓度为30 mg/L、吸附剂质量为0.01 g、pH=5的条件下，高岭石对U(Ⅵ)的吸附效果最好；随着温度的升高，伊利石和高岭石对U(Ⅵ)的吸附能力不断增强，尤其是伊利石；溶液中Mg²⁺、CO^2-₃、HCO^-₃显著降低了伊利石和高岭石对U(Ⅵ)的吸附效果；随着腐殖酸浓度的增加，伊利石对U(Ⅵ)的吸附能力提高，高岭石对U(Ⅵ)的吸附能力降低。     

混炼方式对螺旋纳米碳纤维增强天然橡胶复合材料力学性能的影响

采用干法和湿法两种混炼工艺制备了螺旋纳米碳纤维(HCNFs)/炭黑(CB)/天然橡胶(NR)复合材料,通过扫描电镜、拉伸试验机和应变扫描仪分别对所制备复合材料的界面形貌、力学性能和Payne效应进行了测试分析,考察了混炼方式对复合材料宏观力学性能及Payne效应的影响。结果表明,与纯CB填料相比,在干湿两种混炼方式下,添加适量的HCNFs(1～6份)能提高HCNFs/CB/NR复合材料的300%定伸应力、扯断伸长率、拉伸强度和硬度。与干法混炼相比,湿法混炼能明显增强HCNFs/CB/NR复合材料的Payne效应,并提升在HCNFs高添加量(2～6份)条件下的拉伸强度和扯断伸长率,这主要源于湿法混炼能够有效改善HCNFs在橡胶基质中的分散性。     

The performance of green carbon as a backbone for hydrogen storage materials

We investigate the use of carbonized bamboo, which has an organic porous structure, as a hydrogen storage material. Bamboo samples were thermally treated at 800, 900, 1000, and 1100 °C for 24 h. The pore size and hydrogen storage capacity of each sample were measured by N₂ and H₂ gas sorption up to 1.13 bar at 77 K. The maximum hydrogen storage was exhibited by the sample treated at 900 °C, which reached 1.35 wt% at 1.13 bar/77 K. The results showed that the bamboo, one of the green carbons, has the potential to be used as an environmental-friendly carbon backbone for hybrid hydrogen storage materials.     

Solar driven MgO/Mg based methane reforming and water splitting process: A thermodynamic inspection

The thermodynamic efficiency analysis of the MgO/Mg based CH₄ reforming and H₂O splitting process is performed in this paper. The study is conducted by considering two process configurations, namely, a) MgO/Mg based open process where Mg and syngas is produced (MS process), and b) MgO/Mg based semi-open process where syngas and H₂ is generated (MSH process). The thermodynamic equilibrium analysis indicate that the best possible thermal reduction temperature for both processes is 2100 K and, in case of the MSH process, the water splitting step is feasible in the range of 500–900 K. As per the findings, for the MS process, the solar energy required to drive the process increases by 958.2 kW as the CH₄/MgO ratio upsurges from 0.1 to 1. For the MSH process, the minimum amount of solar energy needed to run the process i.e., 1203.1 kW can be accomplished at water splitting temperature of 900 K and CH₄/MgO molar ratio = 1. Based on the solar-to-fuel energy conversion efficiency, the MSH process appears to be more advantageous (54.5%) than the MS process (41.3%). The solar-to-fuel energy conversion efficiency of the MSH process can be further enhanced up to 65.6% by reclaiming 50% of the heat dissipated by the coolers and WS reactor.     

Surface sedimentation and adherence of Nano‐SiO2 to improve thermal stability and flame resistance of melamine‐formaldehyde foam via sol‐gel method

Melamine‐formaldehyde foam possesses intrinsic flame retardance; however, relative poor thermal stability and a certain amount of heat release rate restrict its applications in heated environment to a degree. In the present research, sol‐gel method has been adopted to precipitate nano‐SiO₂ particles on the surface of the melamine‐formaldehyde foam's fibers to construct a protective inorganic gel layer. Taking advantages of the shielding effects of the gel layer, the thermal‐oxygen degradation of the foam can be greatly retarded during heating; hence, the thermal stability is remarkably improved, and the flame retardance is further enhanced. In addition, introducing a small amount of membrane‐forming agent in the sol‐gel system can make the depositional nano‐SiO₂ particles well adhered to avoid dusting.