Your search keyword '"Ivanov, Alexey"' showing total 5 results

1. The initial magnetic susceptibility of polydisperse ferrofluids: A comparison between experiment and theory over a wide range of concentration.

Author

Solovyova, Anna Y., Goldina, Olga A., Ivanov, Alexey O., Lebedev, Aleksandr V., and Elfimova, Ekaterina A.

Subjects

MAGNETIC susceptibility measurement, MAGNETIC fluids, STATISTICAL mechanics, TEMPERATURE effect, VIRIAL coefficients

Abstract

Temperature dependencies of the static initial magnetic susceptibility for ferrofluids at various concentrations are studied using experiment and statistical-mechanical theories. Magnetic susceptibility measurements are carried out for twelve samples of magnetite-based fluids stabilized with oleic acid over a wide range of temperatures (210K ≲ T ≲ 390); all samples have the same granulometric composition but different volume ferroparticle concentrations (0.2 ≲ φ ≲ 0.5). Experimental results are analyzed using three theories: the second-order modified mean-field theory (MMF2) [A. O. Ivanov and O. B. Kuznetsova, Phys. Rev. E 64, 41405 (2001)]; its correction for polydisperse ferrofluids arising from Mayer-type cluster expansion and taking into account the first terms of the polydisperse second virial coefficient [A. O. Ivanov and E. A. Elfimova, J. Magn. Magn. Mater 374, 327 (2015)]; and a new theory based on MMF2 combined with the first terms of the polydisperse second and third virial contributions to susceptibility. It turns out that the applicability of each theory depends on the experimental sample density. If twelve ferrofluid samples are split into three groups of strong, moderate, and low concentrated fluids, the temperature dependences of the initial magnetic susceptibility in each group are very precisely described by one of the three theories mentioned above. The determination of a universal formula predicting a ferrofluid susceptibility over a broad range of concentrations and temperatures remains as a challenge. [ABSTRACT FROM AUTHOR]

Published

2016

2. Structure factor of model bidisperse ferrofluids with relatively weak interparticle interactions.

Author

Novak, Ekaterina, Minina, Elena, Pyanzina, Elena, Kantorovich, Sofia, and Ivanov, Alexey

Subjects

PHYSICS research, MAGNETIC fluids, THERMODYNAMICS research, MOLECULAR dynamics, PARTICLES (Nuclear physics), MAGNETIC materials

Abstract

In the present manuscript we develop a theoretical approach to describe the pair correlation function of bidisperse magnetic dipolar hard- and soft-spheres. We choose bidisperse system as the first step to allow for polydispersity when studying thermodynamics of magnetic fluids. Using diagram technique we calculate the virial expansion of the pair correlation function up to the first order in density and fourth order in the dipolar strength. Even though, the radial distribution functions are extremely sensitive to the steric potential, we show that the behaviour of the isotropic centre-centre structure factor is almost indifferent to the type of the short-range repulsion. We extensively compare our theoretical results to the data of molecular dynamics simulations, which helps us to understand the range of validity of the virial expansion both on density and magnetic dipolar strength. We also investigate the influence of the granulometric composition on the height, width, and position of the structure factor first peak in order to clarify whether it is possible to extract structural information from experimentally measured small angle neutron scattering intensities. [ABSTRACT FROM AUTHOR]

Published

2013

3. Theory and simulation of anisotropic pair correlations in ferrofluids in magnetic fields.

Author

Elfimova, Ekaterina A., Ivanov, Alexey O., and Camp, Philip J.

Subjects

*MAGNETIC fluids, *ANISOTROPY, *MAGNETIC fields, *COMPUTER simulation, *STATISTICAL correlation, *SEPARATION (Technology), *GAUSSIAN processes

Abstract

Anisotropic pair correlations in ferrofluids exposed to magnetic fields are studied using a combination of statistical-mechanical theory and computer simulations. A simple dipolar hard-sphere model of the magnetic colloidal particles is studied in detail. A virial-expansion theory is constructed for the pair distribution function (PDF) which depends not only on the length of the pair separation vector, but also on its orientation with respect to the field. A detailed comparison is made between the theoretical predictions and accurate simulation data, and it is found that the theory works well for realistic values of the dipolar coupling constant (λ = 1), volume fraction (φ <= 0.1), and magnetic field strength. The structure factor is computed for wavevectors either parallel or perpendicular to the field. The comparison between theory and simulation is generally very good with realistic ferrofluid parameters. For both the PDF and the structure factor, there are some deviations between theory and simulation at uncommonly high dipolar coupling constants, and with very strong magnetic fields. In particular, the theory is less successful at predicting the behavior of the structure factors at very low wavevectors, and perpendicular Gaussian density fluctuations arising from strongly correlated pairs of magnetic particles. Overall, though, the theory provides reliable predictions for the nature and degree of pair correlations in ferrofluids in magnetic fields, and hence should be of use in the design of functional magnetic materials. [ABSTRACT FROM AUTHOR]

Published

2012

4. Magnetophoresis, sedimentation, and diffusion of particles in concentrated magnetic fluids.

Author

Pshenichnikov, Alexander F., Elfimova, Ekaterina A., and Ivanov, Alexey O.

Subjects

PARTICLE dynamics, SEDIMENTATION analysis, DIFFUSION, MAGNETIC fluids, MASS transfer, COLLOIDS, MAGNETIC dipoles, HYDRODYNAMICS

Abstract

A dynamic mass transfer equation for describing magnetophoresis, sedimentation, and gradient diffusion of colloidal particles in concentrated magnetic fluids has been derived. This equation takes into account steric, magnetodipole, and hydrodynamic interparticle interactions. Steric interactions have been investigated using the Carnahan-Starling approximation for a hard-sphere system. In order to study the effective interparticle attraction, the free energy of the dipolar hard-sphere system is represented as a virial expansion with accuracy to the terms quadratic in particle concentration. The virial expansion gives an interpolation formula that fits well the results of computer simulation in a wide range of particle concentrations and interparticle interaction energies. The diffusion coefficient of colloidal particles is written with regard to steric, magnetodipole and hydrodynamic interactions. We thereby laid the foundation for the formulation of boundary-value problems and for calculation of concentration and magnetic fields in the devices (for example, magnetic fluid seals and acceleration sensors), which use a concentrated magnetic fluid as a working fluid. The Monte-Carlo methods and the analytical approach are employed to study the magnetic fluid stratification generated by the gravitational field in a cylinder of finite height. The coefficient of concentration stratification of the magnetic fluid is calculated in relation to the average concentration of particles and the dipolar coupling constant. It is shown that the effective particle attraction causes a many-fold increase in the concentration inhomogeneity of the fluid if the average volume fraction of particles does not exceed 30%. At high volume concentrations steric interactions play a crucial role. [ABSTRACT FROM AUTHOR]

Published

2011

5. Branching points in the low-temperature dipolar hard sphere fluid.

Author

Rovigatti, Lorenzo, Kantorovich, Sofia, Ivanov, Alexey O., Tavares, José Maria, and Sciortino, Francesco

Subjects

BRANCHING processes, HARD-sphere models (Molecular dynamics), MAGNETIC dipoles, THERMODYNAMICS, MONTE Carlo method, MOLECULAR clusters, MOLECULAR self-assembly, COLLOIDS

Abstract

In this contribution, we investigate the low-temperature, low-density behaviour of dipolar hard-sphere (DHS) particles, i.e., hard spheres with dipoles embedded in their centre. We aim at describing the DHS fluid in terms of a network of chains and rings (the fundamental clusters) held together by branching points (defects) of different nature. We first introduce a systematic way of classifying inter-cluster connections according to their topology, and then employ this classification to analyse the geometric and thermodynamic properties of each class of defects, as extracted from state-of-the-art equilibrium Monte Carlo simulations. By computing the average density and energetic cost of each defect class, we find that the relevant contribution to inter-cluster interactions is indeed provided by (rare) three-way junctions and by four-way junctions arising from parallel or anti-parallel locally linear aggregates. All other (numerous) defects are either intra-cluster or associated to low cluster-cluster interaction energies, suggesting that these defects do not play a significant part in the thermodynamic description of the self-assembly processes of dipolar hard spheres. [ABSTRACT FROM AUTHOR]

Published

2013