【摘 要】
:
Studying hydrogen behavior in alloys and the mechanical properties of alloys are essential to various practical uses,such as separation membranes,as well as hyd
【机 构】
:
State Key Laboratory of Solidification Processing,Northwestern Poly technical University,Xi’an 71007
论文部分内容阅读
Studying hydrogen behavior in alloys and the mechanical properties of alloys are essential to various practical uses,such as separation membranes,as well as hydrogen embrittlement protection.In order to further develop the non-Pd-alloy membranes used in hydrogen separation,the mechanical,thermal properties of V14NiM(M= Al,Fe,Si,Ti,Zn)and hydrogen solubility and diffusion behaviors of V-based ternary alloys were studied by first principles calculation.The results indicated that the hydrogen solution energies of V-Ni-M are greater than pure vanadium.And the mono-vacancy in pure vanadium can capture 6 H atoms while the V-Ni-M alloys can only capture 5 H atoms.Therefore,the V-Ni-M alloys exhibit lower solubility of hydrogen and higher brittleness resistance to embrittlement compared with pure vanadium.And the diffusion coefficients of V-Ni-M alloys are smaller than that of pure vanadium thanks to smaller hydrogen solubility.The hydrogen solubility and hydrogen permeability can maintain relatively balanced.The study of mechanical properties suggests that the V-Ni-Ti has the best resistance to deformation and pure vanadium has the best ductility.Moreover,V-Ni-Si alloy has the smallest thermal expansion coefficient in the temperature range of 473-723 K,which is the temperature of hydrogen separation,indicating that V-Ni-Si is the best for hydrogen separation according to thermal properties.
其他文献
A high-performance Mg-4.9Gd-3.2Y-1.1Zn-0.5 Zr alloy has been fabricated by multidirectional forging(MDF)after analyzing its compression behavior.The as-homogeni
The mechanism by which electromagnetic forming(EMF)enhances the formability of metals is unclear owing to the coupling effect of multi-physics fields.In the pre
Developing microwave absorption(MA)materials with satisfied comprehensive performance is a great challenge for tackling severe electromagnetic pollution.In part
各种电子设备的广泛应用,使得电磁辐射与电磁污染日益严重,电磁屏蔽材料应运而生。泡沫复合材料具有密度低,强度高,抗氧化,耐久性强等优点,是一种新型电磁屏蔽材料。本文介绍了电磁屏蔽碳系纳米粒子/聚合物基泡沫复合材料的最新研究进展。基于材料对电磁波的屏蔽机理,重点分析和概述了复合材料中的吸波剂、微观结构及宏观形貌对电磁屏蔽性能的影响。最后对电磁屏蔽碳系纳米粒子/聚合物基泡沫复合材料的未来发展提出了展望。结果表明,对碳系吸波剂进行改性、构建非均匀结构、设计多样化宏观形貌均可提高泡沫复合材料的屏蔽性能。此外,对复杂
利用甚高频等离子体增强化学气相沉积技术,在不同CH4流量下制备非晶SiCx∶H薄膜,在室温下能用肉眼观察到薄膜较强的近红外光发射,并研究其光发射机制。荧光稳态和瞬态光谱分析表明,在不同波长激发下,薄膜的发光光谱谱形及峰位未发生明显变化,并且薄膜的荧光寿命在1~1.5ns之间。经过1100℃退火处理后,随薄膜中硅团簇的析出其发光基本淬灭,研究认为非晶SiCx∶H薄膜的近红外光发射主要源于薄膜中的Si悬键缺陷态发光中心。
本研究采用谷氨酸作为碳源,通过一步水热法制备得到具有良好稳定性和水溶性的氮掺杂碳量子点(N-CQDs)。通过多种表征手段对碳量子点的形态学、表面基团和化学状态进行了分析,结果表明N-CQDs的表面被羧基和氨基功能化。基于六价铬离子(Cr
6+)对碳量子点的荧光淬灭效应,建立了一种灵敏度高、选择性好的Cr
6+荧光检测方法。实验结果表明,Cr
6+对N-CQDs的荧光淬灭程度在Cr6+浓度8~150μmol/L内呈良好的线性关系(R
2
重金属离子污染严重影响着人类的生活环境和身体健康,因此准确检测重金属离子的含量已成为当今环境保护及检测领域亟待解决的问题。针对重金属离子痕量分析困难及传统磁性固相萃取技术存在的萃取容量小、对重金属离子选择萃取性差等缺点,以溶剂热法制备的Fe3O4磁性纳米颗粒为磁核,并配合多巴胺改性及具有丰富端基的聚酰胺-胺树状大分子(PAMAM)接枝设计,制备出具有核壳结构的磁性固相萃取剂Fe3O4/PDA/PAMAM-NH2,用于重
本文对比了二维过渡金属碳(氮)化合物(MXene)的制备方法(氢氟酸刻蚀法、高温刻蚀法和化学气相沉积法);分析了层间距、表面基团和测试环境对MXene材料电化学储能性能的影响,探讨了其结构与电化学储能性能的关系,揭示了不同基体的物理化学性质、微观结构以及基体组成对MXene基复合材料电化学性能的影响。对MXene目前在储能领域应用上存在的问题及未来的发展方向进行了展望。
Exploiting economical and high-efficient electrocatalysts of oxygen evolution reaction(OER)remains urgent in the field of sustainable hydrogen generation by wat
Al2O3和MgO构成的耐火材料已被广泛运用到铜冶炼生产中。但由于熔池熔炼过程中高温及熔渣特性,耐火材料易被侵蚀和老化,尤其是耐火材料与铜熔渣直接接触处。本实验研究了Al2O3坩埚和30%MgO-65%SiO2-5%Al2O3坩埚对炉渣的抗侵蚀能力,探究了熔渣中碱度、Al2O3含量对耐火材料侵蚀行为的影响。研究