Impedance measurements on kerosene-based ferrofluids

IF 2.7 3区物理与天体物理 Q2 PHYSICS, APPLIED

Journal of Applied Physics Pub Date : 2024-09-05 DOI:10.1063/5.0223322

F. Batalioto, K. Parekh, G. Barbero, A. M. Figueiredo Neto

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Abstract

We study the impedance behavior of two ferrofluids, of a similar magnetic material, one constituted by spherical nanoparticles and the other constituted by cubes, both suspended in kerosene. The ferrofluid constituted by cubic nanoparticles has 10% doping of a rare earth ion. The samples were inserted between two parallel disk-like electrodes of area S=2.3cm2 made of surgical steel, separated by d=127μm. The impedance was measured by applying a sinusoidal voltage of amplitude V0=30 mV, from 1 mHz to 100 kHz. To analyze the experimental data, we use a model based on the Poisson–Nernst–Planck equations, with Ohmic boundary conditions. In the analysis, we assume that the ferrofluids contain free ions, originated from the manufacturing process, released by the stabilization layer around the magnetic nanoparticles dispersed in kerosene. The corresponding nanoparticles are charged of opposite signs with respect to these free ions. In the high frequency region, the effective diffusion coefficient coincides with that from the free diffusion coefficients, defined as the mathematical average between the diffusion coefficients of the nanoparticles and the free ions. In the low frequency region, we found the ambipolar diffusion coefficient, defined as their harmonic average. The effect of the electrodes is taken into account by means of surface conductivity to describe the conduction current across the electrode, assumed to be proportional to the surface electric field. In this model, the role of the electrodes is important just in the low frequency region. On the contrary, in the high frequency region, where the electric current is dominated by the displacement current, the role of the electrodes is negligible. The results show that the nanoparticles of the magnetic material have no effects on the higher-frequency range of the impedance spectra. In the low frequency region, our results indicate a difference in the electric response of the two ferrofluids. Due to their similar dimensions and, hence, similar ambipolar diffusion coefficients, we impute the observed different behavior to the charge transfer from the bulk to the external circuit included in the surface conductivity.

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煤油基铁流体的阻抗测量

我们研究了两种磁性材料类似的铁流体的阻抗行为，一种由球形纳米粒子构成，另一种由立方纳米粒子构成，两者都悬浮在煤油中。由立方纳米粒子构成的铁流体掺杂了 10%的稀土离子。样品被放置在两个平行的圆盘状电极之间，这两个电极由外科钢制成，面积 S=2.3 平方厘米，相距 d=127μm。测量阻抗的方法是施加振幅为 V0=30 mV 的正弦电压，频率范围为 1 mHz 至 100 kHz。为了分析实验数据，我们使用了一个基于泊松-奈恩斯特-普朗克方程的模型，该模型具有欧姆边界条件。在分析过程中，我们假定铁流体中含有游离离子，游离离子源于制造过程，由分散在煤油中的磁性纳米粒子周围的稳定层释放出来。相应的纳米粒子带与这些游离离子相反的电荷。在高频区域，有效扩散系数与自由扩散系数相吻合，后者被定义为纳米粒子扩散系数与自由离子扩散系数的数学平均值。在低频区域，我们发现了伏极扩散系数，其定义为它们的谐波平均值。电极的影响是通过表面电导率来描述跨电极的传导电流，假定其与表面电场成正比。在这一模型中，电极的作用仅在低频区域非常重要。相反，在电流由位移电流主导的高频区域，电极的作用可以忽略不计。结果表明，磁性材料的纳米颗粒对阻抗谱的高频范围没有影响。在低频区域，我们的结果表明两种铁流体的电响应存在差异。由于它们的尺寸相似，因此具有相似的极性扩散系数，我们将观察到的不同行为归因于表面电导率中包含的从体到外电路的电荷转移。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Applied Physics 物理-物理：应用

CiteScore

5.40

自引率

9.40%

发文量

1534

审稿时长

2.3 months

期刊介绍： The Journal of Applied Physics (JAP) is an influential international journal publishing significant new experimental and theoretical results of applied physics research. Topics covered in JAP are diverse and reflect the most current applied physics research, including: Dielectrics, ferroelectrics, and multiferroics- Electrical discharges, plasmas, and plasma-surface interactions- Emerging, interdisciplinary, and other fields of applied physics- Magnetism, spintronics, and superconductivity- Organic-Inorganic systems, including organic electronics- Photonics, plasmonics, photovoltaics, lasers, optical materials, and phenomena- Physics of devices and sensors- Physics of materials, including electrical, thermal, mechanical and other properties- Physics of matter under extreme conditions- Physics of nanoscale and low-dimensional systems, including atomic and quantum phenomena- Physics of semiconductors- Soft matter, fluids, and biophysics- Thin films, interfaces, and surfaces