Numerical study of coalescence and non-coalescence of two conducting drops in a non-conducting medium under electric field

Electrochemotherapy is an anticancer treatment based on applying electric field pulses that reduce cell membrane selectivity, allowing chemotherapy drugs to enter the cells. In parallel to electrochemotherapy clinical tests, in silico experiments have helped scientists and clinicians to understand the electric field distribution through anatomically complex regions of the body. In particular, these in silico experiments allow clinicians to predict problems that may arise in treatment effectiveness. The current work presents a metastatic case of a mast cell tumor in a dog. In this specific treatment planning study, we show that using needle electrodes has a possible pitfall. The macroscopic consequence of the electroporation was assessed through a mathematical model of tissue electrical conductivity. Considering the electrical and geometrical characteristics of the case under study, we modeled an ellipsoidal tumor. Initial simulations were based on the European Standard Operating Procedures for electrochemotherapy suggestions, and then different electrodes’ arrangements were evaluated. To avoid blind spots, multiple applications are usually required for large tumors, demanding electrode repositioning. An effective treatment electroporates all the tumor cells. Partially and slightly overlapping the areas increases the session’s duration but also likely increases the treatment’s effectiveness. It is worth noting that for a single application, the needles should not be placed close to the tumor’s borders because effectiveness is highly likely to be lost.

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Stopping electric field extension in a modified nanostructure based on SOI technology - A comprehensive numerical study

Superlattices and Microstructures ◽

10.1016/j.spmi.2017.06.031 ◽

2017 ◽

Vol 111 ◽

pp. 206-220 ◽

Cited By ~ 10

Author(s):

Mohammad K. Anvarifard ◽

Ali A. Orouji

Keyword(s):

Electric Field ◽

Numerical Study ◽

Field Extension ◽

Soi Technology

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NUMERICAL STUDY OF THE INFLUENCE OF DEPOSITION OF A DISPERSED COMPONENT OF A GAS SUSPENSION ON THE DYNAMICS OF GAS DURING DEPOSITION OF A GAS SUSPENSION IN THE ELECTRIC FIELD

Vestnik of Kuzbass State Technical University ◽

10.26730/1999-4125-2021-1-38-45 ◽

2021 ◽

pp. 38-45

Author(s):

Dmitriy A. Tukmakov

Keyword(s):

Electric Field ◽

Numerical Study ◽

Gas Suspension

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Evaluation of Electric Field and Space Charge Dynamics in Dielectric under DC Voltage with Superimposed Switching Impulse

Energies ◽

10.3390/en12101836 ◽

2019 ◽

Vol 12 (10) ◽

pp. 1836 ◽

Cited By ~ 1

Author(s):

Ik-Soo Kwon ◽

Sun-Jin Kim ◽

Mansoor Asif ◽

Bang-Wook Lee

Keyword(s):

Electric Field ◽

Space Charge ◽

Field Distribution ◽

Electric Field Distribution ◽

Numerical Study ◽

Numerical Approach ◽

Dc Voltage ◽

Charge Dynamics ◽

Electrical Stress ◽

Dc Stress

The influx of a switching impulse during DC steady-state operations causes severe electrical stress on the insulation of HVDC cables. Thus, the insulation should be designed to withstand a superimposed switching impulse. All major manufacturers of DC cables perform superimposed switching impulse breakdown tests for prequalification. However, an experimental approach to study space charge dynamics in dielectrics under a switching impulse superposed on DC voltage has not been reported yet. This is because, unlike the DC stress, it is not possible to study the charge dynamics experimentally under complex stresses, such as switching impulse superposition. Hence, in order to predict and investigate the breakdown characteristics, it is necessary to obtain accurate electric field distribution considering space charge dynamics using a numerical approach. Therefore, in this paper, a numerical study on the switching impulse superposition was carried out. The space charge dynamics and its distribution within the dielectric under DC stress were compared with those under a superimposed switching impulse using a bipolar charge transport (BCT) model. In addition, we estimated the effect of a superimposed switching impulse on a DC electric field distribution. It was concluded that the temperature conditions of dielectrics have a significant influence on electric field and space charge dynamics.

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Effects of three-dimensional electric field on saltation during dust storms: An observational and numerical study

10.5194/acp-2019-439 ◽

2019 ◽

Author(s):

Huan Zhang ◽

You-He Zhou

Keyword(s):

Electric Field ◽

Field Data ◽

Numerical Study ◽

Three Dimensional ◽

Vertical Component ◽

Dust Storms ◽

Dust Particles ◽

Sand Transport ◽

Dust Transport ◽

Dust Events

Abstract. Particle tribo-electrification being ubiquitous in nature and industry, potentially plays a key role in dust events, including the lifting and transport of sand and dust particles. However, the properties of electric field (E-field) and its influences on saltation during dust storms remain obscure as the high complexity of dust storms and the existing numerical studies mainly limited to one-dimensional (1-D) E-field. Here, we quantify the effects of real three-dimensional (3-D) E-field on saltation, through a combination of field observations and numerical modelling. The 3-D E-fields in the sub-meter layer from 0.05 to 0.7 m above the ground during a dust storm are measured at Qingtu Lake Observation Array site. The measured results show that each component of the 3-D E-field data nearly collapses on a single 3-order polynomial curve when normalized. Interestingly, the vertical component of the 3-D E-field increases with increasing height in the saltation layer during dust storms. Such 3-D E-field data close to the ground within a few centimeters has never been reported and formulated before. Using the discrete element method, we then develop a comprehensive saltation model, in which the tribo-electrification between particle-particle midair collisions is explicitly accounted for, allowing us to evaluate the tribo-electrification in saltation properly. By combining the results of measurements and modelling, we find that although the vertical component of the E-field (i.e. 1-D E-field) inhibits sand transport, 3-D E-field enhances sand transport substantially. Furthermore, the model predicts that 3-D E-field enhances the total mass flux by up to 63 %. This suggests that a truly 3-D E-field consideration is necessary if one is to explain precisely how the E-field affects saltation during dust storms. These results will further improve our understanding of particle tribo-electrification in saltation and help to provide more accurate characterizations of sand and dust transport during dust storms.

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Control of Dielectric Fluid Flow Distribution in Micro-Tubes With EHD Conduction Pumping: Numerical Study

ASME/JSME 2011 8th Thermal Engineering Joint Conference ◽

10.1115/ajtec2011-44309 ◽

2011 ◽

Author(s):

Miad Yazdani ◽

Jamal Seyed-Yagoobi

Keyword(s):

Fluid Flow ◽

Electric Field ◽

Conduction Mechanism ◽

Numerical Study ◽

Fluid Motion ◽

Flow Distribution ◽

Operating Conditions ◽

Dielectric Fluid ◽

Total Flow ◽

Flow Through

The control of fluid flow distribution in micro-scale tubes is numerically investigated. The flow distribution control is achieved via electric conduction mechanism. In electrohydrodynamic (EHD) conduction pumping, when an electric field is applied to a fluid, dissociation and recombination of electrolytic species produces heterocharge layers in the vicinity of electrodes. Attraction between electrodes and heterocharge layers induces a fluid motion and a net flow is generated if the electrodes are asymmetric. The numerical domain comprises a 2-D manifold attached to two bifurcated tubes with one of the tubes equipped with a bank of uniquely designed EHD-conduction electrodes. In the absence of electric field, the total flow supplied at the manifold’s inlet is equally distributed among the tubes. The EHD-conduction, however, operates as a mechanism to manipulate the flow distribution to allow the flow through one branch surpasses the counterpart of the other branch. Its performance is evaluated under various operating conditions.

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Numerical Study on Electrokinetic Interaction Between a Pair of Cylindrical Colloidal Particles

Volume 12: Micro and Nano Systems, Parts A and B ◽

10.1115/imece2009-10582 ◽

2009 ◽

Author(s):

Dolfred Vijay Fernandes ◽

Sangmo Kang ◽

Yong Kweon Suh

Keyword(s):

Flow Field ◽

Electric Field ◽

Colloidal Particles ◽

Stokes Equations ◽

Separation Efficiency ◽

Numerical Study ◽

Interaction Force ◽

Surface Element ◽

Immersed Boundary ◽

Interaction Forces

Electrophoresis is the motion of dispersed particles relative to a fluid under the influence of an electric field. Presently this phenomenon of electrokinetics is widely used in biotechnology for the separation of proteins, sequencing of polypeptide chains etc. The separation efficiency of these biomolecules is affected by their aggregation. Thus it is important to study the interaction forces between the molecules. In this study we calculate the electrophoretic motion of a pair of colloidal particles under axial electric field. The hydrodynamic and electric double layer (EDL) interaction forces are calculated numerically. The EDL interaction force is calculated from electric field distribution around the particle using Maxwell stress tensor and the hydrodynamic force is calculated from the flow field obtained from the solution of Stokes equations. The continuous forcing approach of immersed boundary method is used to obtain flow field around the moving particles. The EDL distribution around the particles is obtained by solving Poisson-Nernst-Planck (PNP) equations on a hybrid grid system. The EDL interaction force calculated from numerical solution is compared with the one obtained from surface element integration (SEI) method.

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Dielectrophoresis velocities response on tapered electrode profile: simulation and experimental

Microelectronics International ◽

10.1108/mi-06-2018-0037 ◽

2019 ◽

Vol 36 (2) ◽

pp. 45-53

Author(s):

Muhammad Izzuddin Abd Samad ◽

Muhamad Ramdzan Buyong ◽

Shyong Siow Kim ◽

Burhanuddin Yeop Majlis

Keyword(s):

Electric Field ◽

Field Intensity ◽

Particle Velocity ◽

Applied Voltage ◽

Electric Field Intensity ◽

Particle Trajectory ◽

Numerical Study ◽

Time Interval ◽

Content Type ◽

Field Density

Purpose The purpose of this paper is to use a particle velocity measurement technique on a tapered microelectrode device via changes of an applied voltage, which is an enhancement of the electric field density in influencing the dipole moment particles. Polystyrene microbeads (PM) have used to determine the responses of the dielectrophoresis (DEP) voltage based on the particle velocity technique. Design/methodology/approach Analytical modelling was used to simulate the particles’ polarization and their velocity based on the Clausius–Mossotti Factor (CMF) equation. The electric field intensity and DEP forces were simulated through the COMSOL numerical study of the variation of applied voltages such as 5 V p-p, 7 V p-p and 10 V p-p. Experimentally, the particle velocity on a tapered DEP response was quantified via the particle travelling distance over a time interval through a high-speed camera adapted to a high-precision non-contact depth measuring microscope. Findings The result of the particle velocity was found to increase, and the applied voltage has enhanced the particle trajectory on the tapered microelectrode, which confirmed its dependency on the electric field intensity at the top and bottom edges of the electrode. A higher magnitude of particle levitation was recorded with the highest particle velocity of 11.19 ± 4.43 µm/s at 1 MHz on 10 V p-p, compared to the lowest particle velocity with 0.62 ± 0.11 µm/s at 10 kHz on 7 V p-p. Practical implications This research can be applied for high throughout sensitivity and selectivity of particle manipulation in isolating and concentrating biological fluid for biomedical implications. Originality/value The comprehensive manipulation method based on the changes of the electrical potential of the tapered electrode was able to quantify the magnitude of the particle trajectory in accordance with the strong electric field density.

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