微波放电脱除NO

报道一种不用催化剂,一步脱除NO的新方法--常压微波放电法。探讨在(NO,He),(NO.O₂,He)和(NO,O₂,H₂O,He)体系中微波放电脱除NO的差异。研究结果表明,在(NO,He)条件下可实现一步高效脱除NO,在(NO,O₂,He)条件下也可实现80%左右的NO转化,其中N₂的选择性高达80%,而H₂O的加入并未影响N₂的产率。同时发现,随着微波功率的加大,NO转化率也增大,而N₂的选择性增大得更多。最终可达到一个平衡值。最后研究了NO和O₂浓度及气体流量对NO脱除的影响。     

TiO2纳米微粒对聚苯胺性能的影响

纳米微粒具有量子尺寸效应, 其光、电、声及磁等方面的性能与常规材料有显著的不同, 其中以TiO2纳米微粒的电荷载体、光电活性中心、光学微腔和光电特性等特征[1,2]尤为引人注目. 导电聚合物的纳米复合材料是纳米材料的研究热点之一, 在导电材料、电流体和高密度信息存储材料等方面具有良好的应用前景[3]. 在导电聚合物中, 聚苯胺(PANI)因其具有较高的电导率, 原料便宜, 稳定性好而成为目前最有希望获得实际应用的导电聚合物[4～6]. 将纳米微粒和PANI制成复合材料, 其光电性能等与PANI相比均有所改变. 目前已相继有PANI-ZrO2, PANI-MnO2, PANI-SiO2纳米复合材料的报道[7,8], 而有关PANI-TiO2研究工作尚少见报道. 本文制备了PANI-TiO2纳米复合材料, 通过红外光谱、紫外可见光谱及透射电镜等探讨了复合材料的微结构及性能.     

准球面冲击波高压回收装置的研究

研究了以硝基甲烷液体炸药作为冲击波发生源的准球面汇聚冲击波超高压回收装置。在该装置上 ,利用冲击波由金属球体表面向中心汇聚形成的高压 ,对样品进行了冲击处理 ;分析了回收的金属球体内、外破坏情况及金相组织变化。结果表明 :该装置产生的球面冲击波对称性较好 ,样品回收可靠性较高 ;金属球体中心附近压力超过 2 0 7GPa ;对进行超高压冲击条件下的材料回收实验有较高的实用价值。     

浸渍型Cu/Cr基甲醇裂解催化剂的研究(英文)

制备了Ｃｕ／Ｃｒ为基础的浸渍型甲醇裂解催化剂并考察它们的催化性能,研究了Ｋ、Ｍｇ、Ｎｉ、Ｙ等助剂对催化剂性能和结构的影响。利用ＸＲＤ、ＴＰＲ等技术对浸渍型甲醇裂解Ｃｕ／Ｃｒ基催化剂的结构与性能进行了研究．结果表明,虽然Ｃｕ含量明显低于沉淀型Ｃｕ／Ｚｎ／Ａｌ催化剂,Ｃｕ／Ｃｒ基浸渍型催化剂具有更好的活性和稳定性。助剂Ｋ、Ｍｇ、Ｎｉ、Ｙ等能明显提高催化剂的稳定性,但使催化剂的初活性不同程度地降低。Ｋ、Ｍｇ和Ｎｉ能较好地提高催化剂的选择性,而稀土Ｙ对选择性影一不大。     

HELP法在中草药分析中的应用研究

基于直以推导式演进特征投影（ＨＥＬＰ）法,对冬虫夏草子座和虫体分别进行了多组分同时定性定量测定,结果表明,ＨＥＬＰ法能减少样本提取分离的步骤,降低色谱分离条件的要求,提高检测准确度,联用色谱检测与化学计量学解析法相结合将为复杂中草药分析提供一种全新手段。     

高超声速非平衡流动-辐射特性数值模拟研究

飞行器高超声速飞行过程中所承受对流加热和辐射加热可能具有相当的量级,因此合理准确预测气动加热需要将二者进行综合考虑.文章发展了具有非玻尔兹曼电子能级分布和振动能级分布的高温空气碰撞辐射模型,并耦合一维激波后流动方程计算不同飞行条件下激波后的非平衡流动特性,采用逐线辐射输运模型计算获得激波后非平衡辐射特性、辐射强度和辐射输运通量,深入比较分析了不同飞行高度和马赫数对非平衡流动和辐射输运过程的影响.计算结果表明对于高空高马赫飞行条件,其波后流动存在显著的热力学非平衡、化学非平衡和能级非平衡特征,在近激波区域高振动能级和原子高束缚电子激发态明显低于玻尔兹曼分布.在高空高马赫条件下真空紫外辐射占据主导地位,主要是由高能原子束缚-束缚跃迁造成的.随着高度和马赫数的下降,激波层内气体解离和电离程度降低,原子辐射贡献下降,分子辐射贡献增加,导致红外、可见光和紫外波段的辐射输运增强,真空紫外辐射输运过程减弱.     

High-performance synaptic transistors for neuromorphic computing

The further development of traditional von Neumann-architecture computers is limited by the breaking of Moore’s law and the von Neumann bottleneck, which make them unsuitable for future high-performance artificial intelligence (AI)systems. Therefore, new computing paradigms are desperately needed. Inspired by the human brain, neuromorphic computing is proposed to realize AI while reducing power consumption. As one of the basic hardware units for neuromorphic computing, artificial synapses have recently aroused worldwide research interests. Among various electronic devices that mimic biological synapses, synaptic transistors show promising properties, such as the ability to perform signal transmission and learning simultaneously, allowing dynamic spatiotemporal information processing applications. In this article, we provide a review of recent advances in electrolyte-and ferroelectric-gated synaptic transistors. Their structures, materials,working mechanisms, advantages, and disadvantages will be presented. In addition, the challenges of developing advanced synaptic transistors are discussed.     

Effect of pressure on the elastic properties and optoelectronic behavior of Zn_4B_6O_(13): First-principles investigation

The hydrostatic-pressure-dependent mechanical stability and optoelectronic behavior of Zn_4B_6O_(13)(ZBO) are calculated using the exchange-correlation functional Perdew–Burke–Ernzerhof generalized gradient approximation and the hybrid functional PBE0 based on density functional theory. The calculated and experimental unit cell volumes and Vickers hardness of ZBO at zero pressure agree well. ZBO is mechanically stable under the critical pressure of 52.98 GPa according to the generalized stability criteria. Furthermore, Young's modulus and Vickers hardness decrease with increasing hydrostatic pressure. The strength and type of ZBO bonds are investigated by population and electron density difference. The electronic structure at zero pressure reveals that ZBO is an indirect band gap semiconductor, and the calculated 5.62-e V bandgap coincides well with the 5.73-e V experimental value, highlighting the success of the hybrid functional PBE0 calculations of electronic properties. The band gap almost increases as a second-order polynomial of pressure, and the indirect nature does not change with the applied external pressure. The optical reflectivity and absorption coefficient show that ZBO is an excellent ultraviolet photodetector. Our calculation results suggest that the elastic and optical properties of ZBO are highly stable over a wide pressure range.     

Slow Vortex Creep Induced by Strong Grain Boundary Pinning in Advanced Ba122 Superconducting Tapes

We report the temperature, magnetic field and time dependences of magnetization in advanced Ba122 superconducting tapes. The sample exhibits peculiar vortex creep behavior. Below 10 K, the normalized magnetization relaxation rate S = d ln(-M)/d ln(t) shows a temperature-insensitive plateau with a value comparable to that of low-temperature superconductors, which can be explained within the framework of collective creep theory. It then enters into a second collective creep regime when the temperature increases. Interestingly, the relaxation rate below 20 K tends to reach saturation with increasing the field. However, it changes to a power law dependence on the field at a higher temperature. A vortex phase diagram composed of the collective and the plastic creep regions is shown. Benefiting from the strong grain boundary pinning, the advanced Bal22 superconducting tape has potential to be applied not only in liquid helium but also in liquid hydrogen or at temperatures accessible with cryocoolers.     

钨酸锌纳米结构的水热合成及其光催化性能研究

使用柠檬酸钠辅助的水热法合成了具有不同形貌的ZnWO4(如片状、花状)纳米颗粒,并采用X-射线粉末衍射(XRD)、场发射扫描电子显微镜(FESEM)、高分辨透射电子显微镜(HRTEM)等方法对样品的结构和组成进行表征。研究了溶剂组分和溶液pH值对产物形貌的影响。通过对反应产物形貌随时间变化的观察,提出了片状和花状ZnWO4纳米颗粒可能的生长机理。以罗丹明B(RhB)为催化降解对象,对样品在水溶液中的光催化性质进行了研究。结果表明,ZnWO4纳米颗粒的比表面积和孔径尺寸等结构特性对其光催化活性具有明显影响。