High-magnetic-field electromagnetophoresis of micro-particles in a capillary flow system

The electromagnetophoretic migration of micro-particles in a capillary flow system was demonstrated using a homogeneous magnetic field applied at right angles to an electric current. We utilized a high-magnetic-field of 10 T for observing this phenomenon. When the direction of the electric current was alternatively changed, polystyrene latex particles in a flowing aqueous medium migrated zigzag affected by a Lorentz force exerted on the medium. Carbon particles also migrated in the same manner with polystyrene particles. Further, we tried the electromagnetophoretic migration of biological particles, such as yeasts and human red blood cells. The migration velocity component perpendicular to the flow was proportional to both the electric current and the magnetic flux density. These results proved that the dominant force of the zigzag migration was an electromagnetophoretic buoyancy generated in the flowing medium. Moreover, it was found that the force exerted on the particles in the magnetic field of 10 T was sufficient for the desorption of particles adsorbed on the capillary wall.     

Magnetic field effect on autocatalysis: Ag and Cu in concentrated nitric acid

The partial suppression of corrosion of Ag and Cu in concentrated nitric acid solution by a magnetic field of up to 5 T was studied. The corrosion current density of these metals was found to diminish with magnetic field and rotation speed in a rotating disk electrode experiment. The suppression of corrosion is associated with removal of the catalyst HNO(2) from the electrode and passivation of the electrode surface. The Lorentz force was identified as the driving force responsible for the partial suppression of corrosion. A model based on the partial areas associated with active and passive regions on Ag and Cu electrodes is introduced to explain the dependence of the current density on the applied magnetic field.     

Die swell ratio of polystyrene melt from an electro‐magnetized capillary die in an extrusion rheometer: effects of barrel diameter,shear rate and die temperature

A constant shear‐rate extrusion rheometer with an electro‐magnetized capillary die was utilized to investigate die swell behavior and flow properties of a polystyrene melt as the application of an electro‐magnetic field to the capillary die was relatively novel in polymer processing. The test conditions such as magnetic flux density, barrel diameter, extrusion rate and die temperature were studied. The results suggest that the maximum swelling of the polystyrene melt with application of the electro‐magnetic field could be enhanced up to 2.6 times (260%) whereas that without the electro‐magnetic field was 1.9 times (190%). The barrel diameter of 30 mm was found to be a critical value in the case of the die swell ratio and flow properties of the polystyrene melt were significantly affected by the magnetic flux density. This involved the number and angle of magnetic flux lines around the barrel part. Under the electro‐magnetic field, there were two mechanical forces influencing the die swell ratio and the flow properties; magnetic torque and shearing force. The die swell at wall shear rates less than 11.2 sec^?1 was caused by the magnetic torque, whereas at higher wall shear rates it was dependent on the shearing force. For a given magnetic flux density, the maximum increase in the die swell ratio as a result of the magnetic torque was calculated to be approximately 20%. Increasing the die temperature from 180 to 200°C reduced the overall die swell ratio and suppressed the effect of the magnetic flux density. Copyright © 2004 John Wiley & Sons, Ltd.     

Ion transport in electrolyte flux under magnetic field

The problems of distribution of ion concentrations, electric field, and Lorentz force in the flux of the solution of electrolyte under external magnetic field are solved. The existence of the diffuse ion layer in magnetic flow of the dilute electrolyte is established and its characteristics are studied.     

Presence of in-plane anisotropy and oscillatory magnetoresistive behavior in epitaxial SrRuO3 thin films with orthogonal equivalent axes

In-plane magnetic hysteresis measurements performed on thin films of SrRuO₃ (SRO) deposited on (001)-oriented SrTiO₃ substrates showed orthogonal equivalent axes. This finding, nevertheless, was not conclusive argument to discard the presence of in-plane anisotropy in these samples. Certainly, measurements of the in-plane magnetoresistance (MR) featured anisotropic behavior with a well-defined angular dependence. The observed 180° periodicity of the function MR(θ) corresponded to that expected for the standard anisotropic magnetoresistance phenomenon (AMR). On the other hand, the longitudinal MR (zero Lorentz force) and transverse MR (nonzero Lorentz force), recorded at low temperatures and magnetic fields, displayed positive MR with a relatively broad maximum for the first field ramp up to 4 T. For the subsequent field sweep down, MR was negative for all field orientations. The described behavior was symmetric upon reversal of the applied magnetic field leading to a strong hysteretic behavior of MR.     

Role of magnetic forces in electrochemical reactions at microstructures

The effect of an external magnetic field (up to 0.8 T) on the anodic dissolution of microstructures has been investigated systematically. Copper and silver wires (100 microm in diameter) were embedded in epoxy resin and dissolved potentiostatically while a magnetic field was periodically switched on and off. A special feature of the thus prepared structures is that they show a smooth transition from an inlaid disk to a recessed disk electrode. An increase or a decrease of the limiting current density in the presence of B was found depending on the orientation of the magnetic field and the hydrodynamic conditions in the cell (natural or forced convection). The magnetic forces which are responsible for this are the Lorentz force and the gradient force. We propose a model which discusses the interaction of these forces with the natural and the forced convection to explain the experimental results.     

Effect of ampere force on electrolyte flow and current passing due to EMF generation in electrochemical cell rotating in magnetic field

An Ampere force acts in the rotating electrochemical cell, which is located in the magnetic field. This force causes an electrolyte flow directed oppositely to the direction of cell rotation. The effect of Ampere force on the distribution of hydrodynamic velocity in the gap between two cylindrical electrodes of rotating cell is theoretically analyzed. Under certain simplifying assumptions, an equation is obtained for calculating the current passing in the cell by action of potential difference, which arises in the cell due to the Lorentz force taking into account the Ampere force.     

Inhomogeneous electrodeposition of copper in a magnetic field

Normally, magnetoconvection driven by the Lorentz force increases the limiting current in the mass-transport limited regime, roughly as the one-third power of the applied magnetic field. Here we show that an applied field can actually diminish the rate of copper electrodeposition at low overpotentials. The effect is related to the formation of a vortex at the leading edge of the flow. Similar, but weaker effects are due to gravity.     

Migration analysis of micro-particles in liquids using microscopically designed external fields.

The recent development of new migration methods of micro-particles in liquids using various external fields is reviewed. The combination of a laser scattering force and a photothermal effect produced photothermal-conversion laser-photophoresis. A dielectric field generated in a planer or a capillary quadrupole electrode realized dielectrophoresis. Using a micrometer-scaled magnetic field gradient, the "Magnetophoretic velocimetry" of micro-particles was invented. Furthermore, the Lorentz force generated by combining an electric field and a magnetic field was utilized for electromagnetophoresis. These new methods were overlooked and the advantages in analytical use were discussed.     

Motion of a colloidal sphere with interfacial self-electrochemical reactions induced by a magnetic field

The motion of a spherical colloidal particle with spontaneous electrochemical reactions occurring on its surface in an ionic solution subjected to an applied magnetic field is analyzed for an arbitrary zeta potential distribution. The thickness of the electric double layer adjacent to the particle surface is assumed to be much less than the particle radius. The solutions of the Laplace equations governing the magnetic scalar potential and electric potential, respectively, lead to the magnetic flux and electric current density distributions in the particle and fluid phases of arbitrary magnetic permeabilities and electric conductivities. The Stokes equations modified with the Lorentz force contribution for the fluid motion are dealt by using a generalized reciprocal theorem, and closed-form formulas for the translational and angular velocities of the colloidal sphere induced by the magnetohydrodynamic effect are obtained. The dipole and quadrupole moments of the zeta potential distribution over the particle surface cause the particle translation and rotation, respectively. The induced velocities of the particle are unexpectedly significant, and their dependence on the characteristics of the particle-fluid system is physically different from that for electromagnetophoretic particles or phoretic swimmers.     

Deformation of magnetosensitive emulsion microdroplets in magnetic and electric fields

A magnetosensitive emulsion comprising an ensemble of nonmagnetic oil droplets suspended in a kerosene-based magnetic fluid is studied. It is found that the droplets of such an emulsion are deformed in both magnetic and electric fields. The character of microdroplet deformation in the electric field depends on the field frequency: at low frequencies, the droplets are flattened; at high frequencies, the droplets are stretched along the force lines of the field. It is established that the deformation caused by the electric field can be compensated for by the imposition of an additional magnetic field, and the conditions of this compensation are determined. It is revealed that, under the action of a magnetic field directed normal to a thin layer of the emulsion, the droplets “split” into branched structures. The action of a similarly directed alternating electric field leads to the transformation of the droplets into tori followed by their rupture. It is concluded that the structure of the emulsion can be efficiently controlled using the combined action of magnetic and electric fields. Original Russian Text ? Yu.I. Dikanskii, O.A. Nechaeva, A.R. Zakinyan, 2006, published in Kolloidnyi Zhurnal, 2006, Vol. 68, No. 2, pp. 161–165.     

Magnetohydrodynamic effects on a charged colloidal sphere with arbitrary double-layer thickness

An analytical study is presented for the magnetohydrodynamic (MHD) effects on a translating and rotating colloidal sphere in an arbitrary electrolyte solution prescribed with a general flow field and a uniform magnetic field at a steady state. The electric double layer surrounding the charged particle may have an arbitrary thickness relative to the particle radius. Through the use of a simple perturbation method, the Stokes equations modified with an electric force term, including the Lorentz force contribution, are dealt by using a generalized reciprocal theorem. Using the equilibrium double-layer potential distribution from solving the linearized Poisson-Boltzmann equation, we obtain closed-form formulas for the translational and angular velocities of the spherical particle induced by the MHD effects to the leading order. It is found that the MHD effects on the particle movement associated with the translation and rotation of the particle and the ambient fluid are monotonically increasing functions of κa, where κ is the Debye screening parameter and a is the particle radius. Any pure rotational Stokes flow of the electrolyte solution in the presence of the magnetic field exerts no MHD effect on the particle directly in the case of a very thick double layer (κa→0). The MHD effect caused by the pure straining flow of the electrolyte solution can drive the particle to rotate, but it makes no contribution to the translation of the particle.     

Photoinduced orientational order of dichloride anion radicals

The photo-orientation of dichloride anion radicals (Cl₂^−·) in a glassy solution of 5 M LiCl is discussed. The quantitative characteristics of orientation of paramagnetic molecules were determined using the anisotropy of optical absorption and the angular dependence of the EPR spectrum. The orientational distribution function of ordered anion radicals was determined by joint computer modeling of the EPR spectrum recorded at different directions of the symmetry axis of a sample relative to the magnetic field of a spectrometer. It was found that the value of the order parameter (−0.1 ± 0.01), calculated from the orientational distribution function coincides with the value obtained under the measurements of the linear dichroism in the range of the detection error (−0.12 ± 0.01).     

Effects of well-defined magnetic field gradients on the electrodeposition of copper and bismuth

Paramagnetic Cu²⁺-ions have been electrodeposited under application of magnetic field gradients. Obtained deposits show a direct correlation of the distribution of magnetic flux density B at the electrode and the deposit thickness and morphology. In contrast to that no influence on the deposit structure has been observed for deposition of Bi from electrolytes containing diamagnetic Bi³⁺-ions. This indicates that the structuring effect is mainly based on the action of the magnetic gradient force. A structuring-mechanism has been proposed that also discusses influences of the Lorentz force.     

Numerical simulation of the onset of mass transfer and convection in copper electrolysis subjected to a magnetic field

Numerical investigations have been performed in order to simulate the transient behaviour of copper electrolysis in a rectangular cell with vertical electrodes in a galvanostatic regime where the kinetics of the electrodes is controlled by charge-transfer. The transient behaviour observed for a binary electrolyte reproduces the temporal evolution of the concentration distribution measured in recent experimental work. Horizontal magnetic fields that vary linearly between the electrodes create Lorentz forces that either enhance or attenuate natural convection. The different time scales of natural convection and convection driven by the Lorentz force lead to interesting transient effects. The simulations performed for the case of an attenuating Lorentz force explain the dynamics of vertical inhomogeneities of the concentration boundary layer during the initial stages of electrolysis that were previously observed experimentally.     

Electrodeposition Under High Magnetic Field

The film growth under high magnetic field using a super-conducting magnet is discussed from the view point of a magnetization energy. The film configuration in nickel eletrodeposits with and without the high magnetic field was examined by means of the AFM (Atomic Force Microscopy), In the absence of magnetic field, the film surface appeared irregular structure. However, when the magnetic field was imposed in parallel to the cathode plate, nickel deposited shown clearly ordered stationary structure. The experimental results could be explained by nickel magnetic anisotropy. On the other hand, when the field was imposed in perpendicular to a cathode plate, deposition structure is controlled by the fluid motion induced by Lorentz force.     

Influence of constant magnetic field on electrodeposition of metals,alloys, conductive polymers,and organic reactions

The paper presents and summarizes some research on constant magnetic field effects in chemistry. Metals and alloys electrodeposited under constant magnetic field have greater thickness and smoother surface with finest grains. Metallic materials deposited under the influence of uniform magnetic field may have stronger corrosion resistance, than those obtained without the presence of magnetic field. Constant magnetic field also causes an increase of the electropolymerization rate and yield of some organic reactions. Our research also shows that the presence of constant magnetic field affects the electrodeposition process of alloys and their morphology to a great extent. The effects of magnetic field on metals, alloys, composites, polymers and other materials are due to the Lorentz force and the magnetohydrodynamic effect. It is possible that the further development of magnetoelectrodeposition will allow for using the constant magnetic field to improve the properties of metal coatings, alloys, polymers, and other materials in the industry.     

Confinement of paramagnetic ions under magnetic field influence: Lorentz versus concentration gradient force based explanations

Concentration variations observed at circular electrodes with their axis parallel to a magnetic and normal to the gravitational field have previously been attributed elsewhere to the concentration gradient force only. The present paper aims to show that Lorentz force driven convection is a more likely explanation.     

2-氟-5-溴吡啶分子振动光谱的密度泛涵理论研究

用密度泛函理论方法B3LYP以及6-311++G(2df,2pd)基组对2-氟-5-溴吡啶分子 的平衡几何构型进行了优化并计算了该分子的振动谐力场。使用Pulay的标度方法 对理论力场进行了标度。采用Wilson的GF矩阵方法,根据标度后的理论力场进行了 简正坐标分析,对2-氟-5-溴吡啶分子的振动基频进行了理论研究,得到了势能分 布和红外振动频率。与红外频率的实验值相比较,理论频率的均方差为24 cm~(-1) 。此外,根据振动模式的势能分布对此分子的振动基频进行了理论归属,并对前人 的指认进行了修正和补充。     

Effect of Lorentz force on the electrochemical performance of lithium-ion batteries

Lorentz force theory demonstrates that electric current density and magnetic force are proportional, indicating that they compensate each other. In a battery operated at high magnetic forces, the electrons in the active material move fast in a specific magnetic field. γ-Fe₂O₃, a highly magnetic material, is used to prepare LiFePO₄ electrodes to study the effect of the Lorentz force on lithium-ion battery performance. The magnetic field created by γ-Fe₂O₃ induces magnetic forces on the charged LiFePO₄ particles, accelerating electron movement. Superconducting quantum interference measurements reveal that saturation magnetization and remanence are prominent when γ-Fe₂O₃ is added to the LiFePO₄ electrodes. The LiFePO₄ electrode containing 15 wt% γ-Fe₂O₃ led to superior battery capacity (69.8 mAh g^− 1 at 10C) compared with the pure LiFePO₄ electrode (1.8 mAh g^− 1 at 10C). In this study, Lorentz force theory is applied to improve the specific capacity and cycle life at high current rates of a battery containing LiFePO₄ cathode materials, suggesting that incorporating γ-Fe₂O₃ into the cathode is an easy and cheap strategy for increasing the power density and cycle life of lithium-ion batteries.