液体空分流程形式浅析

通过对全液体空分装置不同流程组织形式进行分析和模拟计算、能耗与投资的比较,根据不同规格的产品要求,进行合适的流程形式选择,以可达到节能降耗的目的。     

等示值法在RLC串联谐振电路实验中的应用

研究结果表明采用等示值法在品质因数Q1的情况下,可以精确确定谐振频率,从而实现对电容的精确测定。     

第二个重要极限存在性证明的新方法

本文通过分析第二个重要极限现存的两类典型证明方法,进而提出一种借助本文中证明的一个不等式,得到第二个重要极限存在性证明的新方法.     

基于核酸适体修饰的纳米通道分离β-雌二醇和雌酮的研究

建立了修饰金纳米通道分离β-雌二醇和雌酮的新方法。以聚碳酸酯膜为模板,基于模板合成-化学沉积原理,在其表面及膜孔内壁均匀沉积纳米金层,得到一定孔径的金纳米通道,利用扫描电镜(SEM)、透射电镜(TEM)等对其进行研究表征,制备得到均一、可靠的金纳米通道膜。在制备好的金纳米通道表面,通过分子自组装的方式将β-雌二醇核酸适体修饰在金纳米通道内,得到对β-雌二醇具有选择性的纳米通道。β-雌二醇较容易通过修饰后的纳米通道,而雌酮不易通过。考察了β-雌二醇和雌酮在β-雌二醇核酸适体修饰的金纳米通道的迁移特性,以此实现二者的分离。利用50 nm聚碳酸酯膜沉积金3 h,得到孔径约20 nm金纳米通道膜,在0.5 mmol/L Tris-HCl缓冲溶液(pH 7.4)中,进样池浓度为1.76×10!5mol/L的β-雌二醇和雌酮,分离度达到1.76。     

石墨炉原子吸收法测定PU材料中的铬

采用微波消解技术进行样品前处理,建立了石墨炉原子吸收法测定PU材料中铬含量的方法。在波长429.0 nm下,利用石墨炉程序升温测定,狭缝设为0.5 nm,塞曼效应作为背景校正。标准工作曲线线性良好,相关系数r=0.9986,方法检出限为0.051μg/L,测定结果的相对标准偏差为3.78%,加标回收率为92%～120%(n=6)。该方法简便、可行,适用于PU材料中铬的测定。     

Construction of microscale structures in enclosed microfluidic networks by using a magnetic beads based method

A large number of microscale structures have been used to elaborate flowing control or complex biological and chemical reaction on microfluidic chips. However, it is still inconvenient to fabricate microstructures with different heights (or depths) on the same substrate. These kinds of microstructures can be fabricated by using the photolithography and wet-etching method step by step, but involves time-consuming design and fabrication process, as well as complicated alignment of different masters. In addition, few existing methods can be used to perform fabrication within enclosed microfluidic networks. It is also difficult to change or remove existing microstructures within these networks. In this study, a magnetic-beads-based approach is presented to build microstructures in enclosed microfluidic networks. Electromagnetic field generated by microfabricated conducting wires (coils) is used to manipulate and trap magnetic beads on the bottom surface of a microchannel. These trapped beads are accumulated to form a microscale pile with desired shape, which can adjust liquid flow, dock cells, modify surface, and do some other things as those fabricated microstructures. Once the electromagnetic field is changed, trapped beads may form new shapes or be removed by a liquid flow. Besides being used in microfabrication, this magnetic-beads-based method can be used for novel microfluidic manipulation. It has been validated by forming microscale dam structure for cell docking and modified surface for cell patterning, as well as guiding the growth of neurons.