液体磁铁(磁性液体)的配制方法和性质

使有磁性的微粒均匀地分散在水里,全部液体就像磁铁那样发挥作用。在这个实验中,要研究不容易凝聚的稳定胶体的制作方法及其性质。这种磁性液体(通常叫做磁性流体)有用水作介质的,也有用有机液体做介质的,是很有趣的新物质之一,将来会有很大的用途。     

磁性壳聚糖-聚丙烯酸微球的制备及表征

壳聚糖通过与丙烯酸接枝共聚制得壳聚糖聚丙烯酸悬浮液,在铁磁流体(Fe3O4)与聚乙二醇(分散剂)存在下通过与戊二醛交联,制备了磁性壳聚糖聚丙烯酸微球。用扫描电镜、红外光谱对合成的高分子微球进行形貌观察和结构表征,并进行了元素分析和磁性能测试,研究了磁性微球对牛血清白蛋白(BSA)的吸附效果。结果表明,合成的磁性微球外表呈球形,粒径为100～400nm;当Fe含量为2.47%时,磁性微球的饱和磁化强度约为1.30emug,磁矫顽力为280Oe,磁化率为2.16×10-4(常温下),属于顺磁性材料;其对BSA有较好的吸附效果,饱和吸附量约为400mgg。     

基于磁性分子印迹聚合物的电化学传感器的研究进展

分子印迹聚合物与磁性纳米材料结合,制备成磁性分子印迹纳米敏感膜,这样做不仅可以发挥分子印迹聚合材料的优势,而且磁性纳米粒子可有效提高电化学传感器的灵敏度、稳定性以及生物相容性等。近年来将磁性分子印迹纳米敏感膜应用于电化学传感器制备成的磁性分子印迹电化学传感器得到了较快的发展。本文就近5年来磁性分子印迹电化学传感器敏感膜所用的磁性材料、敏感膜制备方法以及磁性分子印迹电化学传感器在环境、食品以及临床方面的应用进行了综述总结。     

磁性树脂基复合材料的研究进展

综合磁性树脂基复合材料的研究现状,着重介绍了磁性树脂基复合材料的三大类：粘结磁体、磁性高分子微球和磁性离子交换树脂的最新发展和研究状况。     

二维磁性纳米材料的可控合成及磁性调控

自旋电子学的研究重点在于同时利用电子的电荷和自旋两个自由度对信息进行处理和存储,其具有运行速度快、存储密度高和能耗低等优势。毫无疑问,发展二维磁性纳米材料的可控合成方法及磁性调控策略,对于新型自旋电子学器件的构筑具有重要的科学意义和应用价值。然而,目前得到的二维磁性纳米材料的种类十分有限,而且合成方法及磁性调控手段相对单一,极大地限制了该领域的发展。本文首先根据磁性的来源,对二维磁性纳米材料进行了分类,介绍了诱导产生的磁性和具有本征磁性的二维纳米材料,然后详细地归纳了二维磁性纳米材料常见的合成方法,如机械剥离法、电化学剥离法、化学气相沉积法以及液相合成方法等。此外,着重总结了二维材料磁性的主要调控手段,最后展望了该领域遇到的瓶颈、未来的研究重点及应用前景。     

溶液的临界现象

自然界中大量物理体系的相变中存在着临界现象.距今120多年前,人们在流体气-液相变的研究中第一次发现了临界态(称为气-液临界点)的存在.1895年,Pierre Curie 在测量镍的磁性状态方程时观察到铁磁体在某一特征温度(后来称为居里点)以下会产生宏观磁矩.Curie 发现在居里点平均磁矩趋于零的方式与二氧化碳在气-液临界点附近气液二相的密度差     

磁性贵金属纳米催化剂

磁性贵金属纳米颗粒因具有高效的催化性能和可重复利用性而受到广泛关注。本文描述了磁性贵金属纳米颗粒的基本结构,介绍了磁性贵金属催化剂的基本组成部分,概括了磁性贵金属纳米颗粒的制备方法,阐述了国内外磁性贵金属纳米颗粒的创新研究,指出了发展磁性贵金属纳米催化剂亟待解决的问题,并对磁性贵金属纳米颗粒的应用前景进行了展望。     

磁性金属纳米管的制备、形成机理及潜在应用

磁性金属纳米管因其独特的中空结构和优异的催化、磁性及易修饰等性能,逐步发展成为一类重要的功能纳米材料,受到国内外研究人员的广泛关注。本文综述了近年来模板法制备磁性金属纳米管的主要技术,如电沉积、化学沉积、湿模板、原子沉积及水热合成等,重点阐述了硬模板法制备磁性金属纳米管的特殊策略,并针对不同制备策略下的磁性金属纳米管形成机理进行了评述。另外,对硬模板法合成磁性金属纳米管建立了一个机理模型,分别从基底性能、成核环境、生长环境三方面对磁性纳米管的形成机理进行了探讨。最后简单介绍了磁性金属纳米管的性能及潜在应用,并展望了该领域的发展趋势。     

磁性微纳米材料的功能化及其在食物样品前处理中的应用进展

磁性固相萃取是当前对复杂样品中痕量目标物进行有效分离富集的热门技术,功能化磁性微纳米粒子是该技术应用中的关键材料。本文综述了各种已报道的功能化磁性微纳米材料,总结了包括表面嫁接有机小分子、表面包覆碳或无机氧化物、表面嫁接或包覆聚合物、载体表面或孔道内负载磁性纳米粒子、载体骨架内掺入磁性纳米粒子、物理共混法制备磁性功能材料在内的6种功能化方法,并对功能化磁性微纳米材料在食物样品前处理中的应用进行了简要评述。     

磁应答型药物递送载体的设计与构建

复合磁性生物材料的发展和应用已引起生物医学领域的极大关注。磁性纳米粒子因其易功能化而具有靶向药物传递、可控药物释放及磁成像特性逐渐成为药物传递和新型诊疗领域最有前途的材料之一。基于磁性纳米粒子或掺杂的铁氧化物构建的远程触发磁性载药递送系统,有望实现在运输过程中携载药物不泄露的情况下,提高药物递送效率且对病灶周围的健康细胞无毒或低毒性。为构建理想的可控靶向磁性药物递送系统,多种材料或配体可以与磁性纳米粒子复合来构建更安全有效的磁性药物递送系统。一些生物分子、聚合物及天然产物等通过与磁性纳米粒子相结合,构建出可用于药物传递且具有独特性质的磁性复合新材料。迄今为止,具有磁场应答能力的磁性药物递送载体已经在远程控制药物释放领域得到了长足发展。本文总结了近年来磁性药物递送载体作为远程控制治疗体系在设计与构建上的研究进展。重点关注了磷脂分子、聚合物、多孔微纳米材料以及天然产物等与其构建的复合材料,并对当前磁性复合特定给药载体的优点、局限及发展前景等做了简要阐述。     

水基自形成CoFe2O4 磁性液体的零磁场粘滞特性

The plot of viscosity versus particle volume fraction for the water carrier of self-formed CoFe2O4 magnetic fluid is abnormal in zero magnetic field. However,the viscosity theory of the suspension with the global rigid particle filling cannot explain the experiment well. That is because the nanoparticles have aggregated before preparation of magnetic fluid. The fact is found that the sedimentation without magnetic field and the becoming chains in magnetic field of this type of magnetic fluid need the big particles which core are pre-aggregates by researching the interaction of particles of magnetic fluid. Around the big particles,nanoparticles are absorbed with the type of dynamic state. It is on that idea that the model of fluctuant aggregation is made. So,the average diameter,Einstein ratio and particles size distributive deviation of free suspended bodies in zero magnetic fluid are the functions of the particles volume fraction. And then,Popplewell’s formula of the viscosity is modified with this model. As a result,a well-fitted curve is obtained.     

Size-selective chemical synthesis of tartrate stabilized cobalt ferrite ionic magnetic fluid

Ionic magnetic fluid (ferrofluid) is a stable suspension of magnetic nanoparticles in water. Cobalt ferrite nanoparticles are interesting in view of high-density recording storage. The size of the magnetic particles strongly influences the physical properties of the ferrofluids. In this study, we describe the synthesis of ionic magnetic fluid in the presence of tartrate ions. By varying the amount of organic ligands, nanoparticles in a large range of size are obtained: the mean diameter varies from 3 to 10 nm. The effect of tartrate ions on the stability of the ionic magnetic fluid is also studied in relation with the size of the magnetic particles and the amount of adsorbed ligand.     

Destabilizing effect of time-dependent oblique magnetic field on magnetic fluids streaming in porous media

The present work studies Kelvin-Helmholtz waves propagating between two magnetic fluids. The system is composed of two semi-infinite magnetic fluids streaming throughout porous media. The system is influenced by an oblique magnetic field. The solution of the linearized equations of motion under the boundary conditions leads to deriving the Mathieu equation governing the interfacial displacement and having complex coefficients. The stability criteria are discussed theoretically and numerically, from which stability diagrams are obtained. Regions of stability and instability are identified for the magnetic fields versus the wavenumber. It is found that the increase of the fluid density ratio, the fluid velocity ratio, the upper viscosity, and the lower porous permeability play a stabilizing role in the stability behavior in the presence of an oscillating vertical magnetic field or in the presence of an oscillating tangential magnetic field. The increase of the fluid viscosity plays a stabilizing role and can be used to retard the destabilizing influence for the vertical magnetic field. Dual roles are observed for the fluid velocity in the stability criteria. It is found that the field frequency plays against the constant part for the magnetic field.     

Nanodrop of an Ising magnetic fluid on a solid surface

The density functional theory of inhomogeneous simple fluids is extended to an Ising magnetic fluid in contact with a solid surface, which is subjected to an external uniform or nonuniform magnetic field. The system is described by two coupled integral equations regarding the magnetic moment and fluid density distributions. The dependence of the contact angle that a nanodrop makes with the solid surface on the parameters involved in the magnetic interactions between the molecules of fluid and between the molecules of fluid and an external magnetic field is calculated. For the uniform magnetic field, the contact angle increases with increasing magnetic field, approaching an asymptotic value that depends on the strength of the fluid-fluid magnetic interactions. In the nonuniform field generated by a permanent magnet, the contact angle first increases with increasing magnetic field B(M) and then decreases, with the decrease being almost linear for large values of B(M). The obtained results are in qualitative agreement with the experimental data on the contact angle of magnetic drops on a solid surface available in the literature.     

Magnetically actuated artificial cilia: the effect of fluid inertia

Natural cilia are hairlike microtubule-based structures that are able to move fluid on the micrometer scale using asymmetric motion. In this article, we follow a biomimetic approach to design artificial cilia lining the inner surfaces of microfluidic channels with the goal of propelling fluid. The artificial cilia consist of polymer films filled with superparamagnetic nanoparticles, which can mimic the motion of natural cilia when subjected to a rotating magnetic field. To obtain the magnetic field and associated magnetization local to the cilia, we solve the Maxwell equations, from which the magnetic body moments and forces can be deduced. To obtain the ciliary motion, we solve the dynamic equations of motion, which are then fully coupled to the Navier-Stokes equations that describe the fluid flow around the cilia, thus taking full account of fluid inertial forces. The dimensionless parameters that govern the deformation behavior of the cilia and the associated fluid flow are arrived at using the principle of virtual work. The physical response of the cilia and the fluid flow for different combinations of elastic, fluid viscous, and inertia forces are identified.     

具有光导性的磁性高分子微球——反应性铁酞菁与苯乙烯共聚

合成出了带有反应性基团的铁酞菁单体 ,并实现了与苯乙烯单体在磁流体存在下的分散聚合而得磁性高分子微球 .研究了微球结构、组成 ,测定了其磁响应性和光导性     

Physicochemical and Acoustic Properties of Water-Based Magnetic Colloid

A velocity and absorption coefficient of sound for magnetic fluid (MF) based on water are studied in the frequency range of 12–132 MHz as a function of the concentration of dispersed phase, the uniform magnetic field, the storage time, and the temperature. The MF dispersed phase consist of magnetite Fe₃O₄ particles stabilized with sodium oleate. The parameters of sound propagation are measured within temperature interval 0–80°C. Densities of MF and sodium oleate are also measured as a function of temperature. Volume concentrations of magnetic fluid components (water, magnetite, and sodium oleate adsorbed on the surface of magnetic particles) are determined. Densities, heat capacities, coefficients of heat conductivity and thermal expansion of aggregates are estimated. Aggregate size distribution in the studied magnetic fluid is described by the log-normal function. Parameters characterizing the aggregate size distribution are determined and their interpretation is given.     

磁性液体的合成及生物医学应用

本文综述了纳米磁粉的化学合成及磁性液体的一般制备方法及其磁性、磁流变性和磁熵热效应等在靶向给药、栓塞治疗、温热治疗上的应用。     

超顺磁性高分子微球的制备与表征

用化学共沉淀方法制备了Fe3O4纳米微粒,并用油酸(十八烯酸)和十二烷基苯磺酸钠为双层表面活性剂进行表面修饰,制备了稳定的水分散性纳米Fe3O4可聚合磁流体.在Fe3O4磁流体存在下,将苯乙烯与甲基丙烯酸通过乳液聚合方法制备了磁性高分子微球.透射电镜研究表明,Fe3O4微粒的平均粒径在10nm左右,乳液聚合形成的磁性高分子微球的粒径平均约为130nm;用超导量子干涉仪对微粒及高分子微球进行了磁性表征,结果表明,合成的Fe3O4纳米微粒以及磁性高分子微球均具有超顺磁性.同时,还用红外光谱及X射线衍射表征了磁性高分子微球的化学成分和晶体结构.用热失重方法测得磁性高分子微球中磁性物质的含量为23.6%.     

磁流变液组分对其沉降性影响的研究进展

磁流变液是一种形态和性能受外加磁场控制的新型智能材料。在汽车、建筑、医疗、航空航天多种领域具有重要的应用价值,但磁流变液沉降性问题一直是影响其广泛应用的难题。因此,首先从载液、磁性颗粒和添加剂三方面出发,简要回顾了近几年在磁流变液沉降性方面的研究,指出了影响磁流变液沉降性的因素主要有：载液的粘度、磁性颗粒的形状和尺寸、磁性颗粒与载液之间的密度差、添加剂的种类与添加量等。并给出了有效提高磁流变液沉降性的可行策略,最后从磁流变液的沉降现象与应用方面对沉降性研究进行了展望。