磁性编码器演示仪原理

介绍了磁性编码器演示仪的整机结构,磁性编码器内部核心部件——磁头和磁鼓.详细介绍了各向异性磁电阻磁头和CoP磁鼓的制作方法以及工作原理.     

"曲线运动"演示装置的制作

利用磁铁能在磁性画板上留下轨迹的特点,制作了曲线运动演示仪,该演示仪能够直观地演示曲线运动的速度方向和运动规律,该装置操作简单、效果明显.     

液体压强与流速关系实验演示仪

传统液体压强与流速关系实验中,通过横截面积判断液体流速,实验现象不直观.针对该问题,自制了液体压强与流速关系演示仪,该演示仪上设计了高压显示管、低压显示管、测压器和测速器,通过高压显示管和低压显示管中液体的高度直观地显示了液体的压强,同时通过测压器和测速器直接读出了对应的压强和速度,清晰显示液体压强和流速的关系.     

磁性液体薄膜的折射率在外加磁场作用下的变化特性研究

用两块玻璃夹持一层几个μm厚的磁性液体薄膜.将这一磁性液体薄膜垂直放置于由亥姆霍兹线圈建立的均匀磁场中.在迈克尔孙干涉仪上用对比测量法测量在不同外加磁场强度作用下磁性液体薄膜的折射率.实验发现, 磁性液体薄膜的折射率随外加磁场强度的变化而变化.结合实验研究, 提出了外加磁场改变了磁性液体颗粒链的大小, 改变了磁性颗粒链的大小和入射光波波长的比值, 从而改变了磁性液体的折射率的设想.初步建立起了磁性液体薄膜的折射率和外加磁场强度之间的关联式.为磁场测量、光学阀门等新型磁光器件的开发提供了新的技术.     

均匀磁场中磁性液体的磁表面张力系数实验研究

基于特殊性能的磁性液体增设了综合性设计性实验项目,根据项目式教学法初步实现了以学生自我训练为主的教学模式.本文设计了磁性液体磁表面张力系数智能测试仪,研究了均匀磁场中4种不同类型磁性液体的磁表面张力系数随磁感应强度的变化规律.随外加磁场磁感应强度的增强,磁性液体的磁表面张力系数增大,主要是磁场增强了磁性颗粒之间的相互作用力.磁感应强度相同时,载液质量对磁性液体的磁表面张力系数影响较大,载液质量越小,单位体积内融入的磁性颗粒数量越多,导致磁性液体的磁表面张力系数越大.表面活性剂种类对磁性液体磁表面张力系数的影响也较大,由于油酸对磁性颗粒的吸附作用比PBSI-941表面活性剂强,油酸官能团较早吸附在磁性颗粒表面,限制了磁性颗粒进一步长大,导致MFO-4磁性液体磁表面张力系数较小.     

流线演示仪的制作及应用

利用有机玻璃、排水管、水阀染料容器板等制作了流线演示仪,采用对工作液体染色的方法,避免了工作液体和有色液体的压力差.利用本仪器,对圆形障碍物、流线体和机翼模型周围的流线进行演示,流线稳定、清晰.     

磁性液体磁表面张力测试及其液膜拉脱过程受力分析

使用拉脱法测量了磁性液体的磁表面张力,根据计算机实时采集电压随时间的变化数据得到U-t曲线,进而将液膜拉脱过程分为6个阶段,分别研究了每个阶段的电压变化原因.无外加磁场作用时2F号磁性液体存在一电压变化较平缓的阶段,而白油和1F磁性液体并未出现此现象,这主要是因为白油和1F磁性液体表面张力较大,2F号磁性液体的表面张力较小造成.有外加磁场作用时,磁性液体的磁表面张力增加,主要是由于外加磁场增强了磁性颗粒之间的相互作用.     

光纤导光物理条件与数值孔径物理意义演示仪

由水槽、不同折射率的导光条、支架、半导体激光器及底座构成了演示仪,有机玻璃和石英玻璃导光条用于模拟不同折射率的光纤纤芯,水槽内的透明液体用于模拟光纤的包层.使用演示仪可以模拟演示光纤导光的物理条件与数值孔径的物理意义.     

CoFe2O4自形成磁性液体场致结构化对磁化的影响

因为磁性液体的磁性微粒有着很强的相互作用,Langevin顺磁理论不能很好描述磁性液体的磁化强度随外磁场的变化.研究认为影响磁化的主要因素是磁性液体内微粒整体的结构化,其结构的形成储存了部分磁化功,直接或间接地影响了磁化.在此基础上提出“压缩”模型,修正了描述磁性液体常用的Langevin函数,得出了与实验较好符合的曲线.所提出的一个压缩后等效体积分数与外磁场强度的关系式,近似地描述了磁性液体在磁场中磁化的过程.由修正式得出了近似初始磁化率随体积分数变化关系.     

磁性液体和它的应用

一、引 言 磁性液体(Magnetic fluids),有时也称为磁流体,是指具有磁性的,可以流动的液体.确切地讲,磁性液体是一种将强磁性微粉(100A左右)分散在液相中所得到的非常稳定的胶态溶液.我们在这里着重介绍具有铁磁性的磁性液体. 我们知道,有一些固体是铁磁性材料,有着较强的磁性.所以,将很细小的固体铁磁性颗粒分散到如水等溶液中,它们仍然是可以被磁化的.这样便可获得均匀的液体态磁性材料,它象固体一样具有磁牲。却又保留了液体的性质. 磁性液体首先在1965年由美国国家航空和宇宙航行局(NASA)试制成功.近年来,由于它的奇特的性质,引起了人…     

Si被注入Gd后的磁性及其整流特性的研究

采用离子束技术，在n型硅基片中注入稀土元素钆，制备了磁性-非磁性p-n结.磁性层Gd_xSi_1-x表现出优良的磁学性能，高居里温度，高原子磁矩(利用RKKY模 型 可以得到解释)，低矫顽力，并保持着半导体的属性，磁性-非磁性p-n结具有整流特性，但 没有观察到明显的磁电阻效应. 关键词： 磁性半导体 磁性p-n结 钆的硅化物 离子束外延     

非磁性微球掺杂对纳米磁流体场诱导双折射特性的影响

利用二氧化硅和聚苯乙烯非磁性微球掺入铁氧体纯磁流体中,制得了复合磁流体.定性地研究了复合磁流体在外磁场作用下的双折射与非磁性微球的种类、掺杂浓度以及纯磁流体自身浓度的关系.研究表明,不同浓度的纯磁流体掺杂等量的聚苯乙烯微球对其双折射随磁场的变化趋势影响不同|同一浓度的纯磁流体掺杂不同种类的非磁性微球,对其双折射的影响也不同|掺杂等量但不同比例的两种非磁性混合微球所形成的复合磁流体中,其中一种非磁性微球对其双折射的影响起主导作用,使得该复合磁流体双折射随磁场的变化趋势与起主导作用的非磁性微球单独掺杂时相似.     

Two-dimensional Monte Carlo simulations of structures of a suspension comprised of magnetic and nonmagnetic particles in uniform magnetic fields

The structures of suspensions comprised of magnetic and nonmagnetic particles in magnetic fields are studied using two-dimensional Monte Carlo simulations. The magnetic interaction among magnetic particles, magnetic field strength, and concentrations of both magnetic and nonmagnetic particles are considered as key influencing factors in the present work. The results show that chain-like clusters of magnetic particles are formed along the field direction. The size of the clusters increases with increasing magnetic interaction between magnetic particles, while it keeps nearly unchanged as the field strength increases. As the concentration of magnetic particles increases, both the number and size of the clusters increase. Moreover, nonmagnetic particles are found to hinder the migration of magnetic ones. As the concentration of nonmagnetic particles increases, the hindrance on migration of magnetic particles is enhanced.     

Spin polarization of electrons in magnetic heterostructures

The scattering of nonspin-polarized electrons on a heterostructure containing a magnetic element (a nonmagnetic barrier adjoining a magnetic one from left or right, or a magnetic well between two nonmagnetic barriers) is considered. The transmission coefficients and degrees of the spin polarization of electrons transmitted through these structures are obtained.     

磁性液体在磁场中产生光的双折射效应机理

磁性液体是一种特殊的高分子稳定胶体,在磁场中会产生光的双折射效应,对磁性液体在胶体学科方面展开研究,发现磁性液体在磁场中的弱絮凝行为表现异常明显,显示出特有的方向性,且又不至胶体系统失稳,证明了磁性液体中的磁性微粒在磁场中聚集成方向性的链状而又不失稳的临界状态存在。从而揭示了方向性弱絮凝是磁性液体在磁场中产生光的双折射效应的机理。     

两个非磁性颗粒在磁流体中的沉降现象研究

在磁场作用下,在磁流体里添加非磁性颗粒(non-magnetic particles,NPs),可以使得NPs形成不同的结构,操控NPs的运动从而影响磁流体的特性,这种应用逐渐受到了研究者的关注.为了更好地操控磁流体里NPs的运动,本文采用一种多物理模型研究在外加磁场作用下,磁流体中两个NPs沉降的运动过程.其中,用格子玻尔兹曼方法模拟磁流体的运动,外加磁场对磁流体的影响用一种自修正方法求解泊松方程,这个自修正方法可以使欧姆定律满足守恒定律.NPs之间的偶极干扰力采用偶极力模型,同时采用一种相对过渡平滑的共轭边界条件处理NPs与磁流体交界面的流固干扰以避免磁场密度过渡的突变.本文主要探究两个NPs在磁流体中的沉降,揭示磁场作用下NPs的相互干扰原理;同时,对控制NPs运动时的参数进行调节,得到NPs不同的运动轨迹,达到操控颗粒运动的目的.本研究可对NPs在磁流体中的应用提供定量的分析结果,对NPs在工业上的应用提供有力的理论支撑.     

Computer simulation of structures and distributions of particles in MAGIC fluid

MAGIC (MAG-netic Intelligent Compound) is a solidified magnetic ferrofluid (MF) containing both magnetic particles (MPs) and abrasive particles (APs, nonmagnetic) of micron size. The distribution of APs in MAGIC can be controlled by applying a magnetic field during cooling process of MAGIC fluid. In this paper, the influences of magnetic field, size and concentration of particles on the final structures of MPs and the distributions of APs in MAGIC fluid are preliminarily investigated using Stokesian dynamic (SD) simulation method. Simulation results show that MPs prefer to form strip-like structures in MAGIC fluid, the reason for this phenomenon is mainly attributed to the strong dipolar interactions between them. It is also found that MPs prefer to form big agglomerations in weak magnetic field while chains and strip-like structures in strong magnetic field; no long chains or strip-like structures of MPs are observed in low-concentration MAGIC fluid; and for big-size MPs, pure wall-like structures are formed. Evaluation on the distribution of APs with uniformity coefficient shows that strong magnetic field, high concentration and small-size particles can induce more uniform distribution of APs in MAGIC fluid, the uniformity of APs in MAGIC is about 10% higher than that in normal grinding tools.     

Ferromagnetic clusters induced by a nonmagnetic random disorder in diluted magnetic semiconductors

In this work, we analyze the nonmagnetic random disorder leading to a formation of ferromagnetic clusters in diluted magnetic semiconductors. The nonmagnetic random disorder arises from randomness in the host lattice. Including the disorder to the Kondo lattice model with random distribution of magnetic dopants, the ferromagnetic–paramagnetic transition in the system is investigated in the framework of dynamical mean-field theory. At a certain low temperature one finds a fraction of ferromagnetic sites transiting to the paramagnetic state. Enlarging the nonmagnetic random disorder strength, the paramagnetic regimes expand resulting in the formation of the ferromagnetic clusters.     

Magnetism induced by nonmagnetic dopants in zinc-blende SiC: First-principle calculations

Magnetism induced by the nonmagnetic dopants in the zinc-blende SiC (3C-SiC) is investigated by first-principle calculations. The atoms of the first 20 elements in the periodic table except inert gas are used to replace either Si or C atoms as dopants. We find that some nonmagnetic substitutional dopants (mainly the Group IA, Group IIA, Group IIIB, and Group VIIB elements) prefer the spin-polarized ground states with local magnetic moments. In general, the condition for obtaining the local magnetic moments and the magnetic ground state requires that the dopants are p-type and have large electronegativity difference from the neighboring host atoms. The magnetic moments can be tuned over a range between 1 μ B and 3 μ B by doping with the nonmagnetic elements. The nearest-neighbor exchange couplings J 0 between the local magnetic moments are quite large and the codoping method is proposed to increase the dopant concentration. These imply that the nonmagnetic doping in SiC may exhibit collective magnetism. Moreover, the Group IIA Mg and Ca atoms substituting the preferred Si atoms favor the ferromagnetic ground states with the half-metallic electronic properties, which suggests that Mg or Ca substitutional doping on the Si sites in SiC could be a potential route to fabricating the diluted magnetic semiconductors.     

The effect of the ferromagnetic metal layer on tunnelling conductance and magnetoresistance in double magnetic planar junctions

Based on the free-electron approximation,we investigate the effect of the ferromagnetic metal layer on the tunnelling magnetoresistance(TMR) and tunnelling conductance(TC)in the double magnetic tunnel junctions(DMTJs) of the structure NM/FM/I(S)/NM/I(S)/FM/NM,where FM,NM and I(S) represent the ferromagnetic metal,nonmagetic metal and insulator(Semiconductor),respectively,The FM,I(S)and inner NM layers are of finite thickness,while the thickness of the outer NM layer is infinite.The calculated results show that,due to the spin-dependent interfacial potential barriers caused by electronic band mismatch between the various magnetic and nonmagnetic layers,the dependences of the TMR and TC on the thicknesses of the FM layers exhibit oscillations,and a much higher TMR can be obtained for suitable thicknesses of FM layers.