Influence of inclined Lorentz forces through a porous media on squeezing Cu-H2o nanofluid in the presence of heat source/sink

Mousavisani, Seyedmohammad; Khalesi, Javad; Golbaharan, Hossein; Sepehr, Mohammad Noori; Ganji, D.D.

doi:10.1108/hff-03-2019-0186

Cited by 18 publications

(13 citation statements)

References 37 publications

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“…All the atoms in the system interact according to Lennard-Jones (LJ) 12-6 potential function, however with different parameters for argon-argon and carbon-argon interactions. 12 6…”

Section: Simulationmentioning

confidence: 99%

“…Micro-scale fluid flow structure in microchannels or over cylinders, the physical interactions between them have become subject of many investigations recently [4,5]. An important subject in these studies was to investigate the behavior of flow and also the exerted force between that and the cylinder [6][7][8][9][10][11][12][13][14][15]. In recent years, the study of fluid flow in nanoscale has become a subject of interest, especially the direct interactions of flow and carbon nanotubes, which behave like cylindrical fibers in many aspects, with respect to a high number of applications for that and also the unusual properties of them [8,[16][17][18].…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of liquid argon flow around carbon nanotube

Arabghahestani¹,

Sheikhshahrokhdehkordi²,

Akafuah³

2020

Preprint

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In this work non-equilibrium molecular dynamics (MD) simulations were performed to investigate the liquid argon flow passing a stationary carbon nanotube and to estimate kinetic energy of the flow and flow forces exerted on the nanotube. Effects of different factors were also investigated. CFD simulations of flow around a circular cylinder were also performed to compare the results with those of MD around the carbon nanotube. In molecular dynamics simulation, the fluid forces on the body are calculated directly from the summation of the molecular forces exerted on solid atoms by fluid atoms. In this work, this method is used to investigate the effects of different flow parameters such as flow velocity, flow temperature on the flow behavior over the carbon nanotube, atom positioning around the nanotube and forces exerted on it. The simulation is 3D, and the computational domain consists of a maximum of 33,700 liquid argon atoms as the fluid and 240 atoms of carbon which represent the solid nanotube. A single-walled carbon nanotube is simulated as a rigid body of fixed carbon atoms, and both argon-argon and argon-carbon interactions are modeled by the standard Lennard-Jonnes potential function. Flow is driven by rescaling fluid particles velocities at the inlet region with a length of 3% of the domain length in that direction every 50-time steps. Based on the information given, a parallel code was developed, and investigations have been conducted using this code. Results show that among all the parameters which were investigated in this paper, the flow velocity has the most significant effects on the exerted forces and kinetic energy on the carbon nanotube and the drag force is increased with an increment of the flow inlet velocity in all cases. Lift fluctuates around zero in all cases of the stationary carbon nanotube. Inlet flow velocities and temperatures have also changed atoms positioning in the vicinity of the nanotube and so atomic density in the nearby bins which is used to further clarify the difference in the drag force.

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“…All the atoms in the system interact according to Lennard-Jones (LJ) 12-6 potential function, however with different parameters for argon-argon and carbon-argon interactions. 12 6…”

Section: Simulationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dynamics of liquid argon flow around carbon nanotube

Arabghahestani¹,

Sheikhshahrokhdehkordi²,

Akafuah³

2020

Preprint

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“…Note that there is another force, Saffman force, which is channel center/wall-directed lift force experienced by particles lagging/leading the fluid and it is not shown in the figure to avoid confusions. Qualitatively, in most of the literature, that relied on passive techniques, and in a fair amount of the literature, focused on active approaches, the numerical simulation had been used to refine the Qualitatively, in most of the literature, that relied on passive techniques, and in a fair amount of the literature, focused on active approaches, the numerical simulation had been used to refine the understanding of physical phenomena, or/and optimize micro-channel geometrical aspects [41][42][43][44][45][46][47][48][49]. It is noteworthy that herein, we focus mostly on separating and trapping techniques on mammalian cells that are passive and suspended inflow.…”

Section: Microfluidic Systems For Cellular Flow Manipulationmentioning

confidence: 99%

“…understanding of physical phenomena, or/and optimize micro-channel geometrical aspects [41][42][43][44][45][46][47][48][49]. It is noteworthy that herein, we focus mostly on separating and trapping techniques on mammalian cells that are passive and suspended inflow.…”

Section: Appl Sci 2019 9 X For Peer Review 3 Of 23mentioning

confidence: 99%

Advances in Computational Fluid Mechanics in Cellular Flow Manipulation: A Review

2019

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Recently, remarkable developments have taken place, leading to significant improvements in microfluidic methods to capture subtle biological effects down to single cells. As microfluidic devices are getting sophisticated, design optimization through experimentations is becoming more challenging. As a result, numerical simulations have contributed to this trend by offering a better understanding of cellular microenvironments hydrodynamics and optimizing the functionality of the current/emerging designs. The need for new marketable designs with advantageous hydrodynamics invokes easier access to efficient as well as time-conservative numerical simulations to provide screening over cellular microenvironments, and to emulate physiological conditions with high accuracy. Therefore, an excerpt overview on how each numerical methodology and associated handling software works, and how they differ in handling underlying hydrodynamic of lab-on-chip microfluidic is crucial. These numerical means rely on molecular and continuum levels of numerical simulations. The current review aims to serve as a guideline for researchers in this area by presenting a comprehensive characterization of various relevant simulation techniques.

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“…It is recorded from their investigation that amplifying magnetic number decreases the velocity profile and the opposite trend is noticed for the thermal profile in the flow regime. The detailed information on squeezing flows through different flow configurations and their applications and advantages can be found in the literature 34‐44 …”

Section: Introductionmentioning

confidence: 99%

A generalized perspective of magnetized radiative squeezed flow of viscous fluid between two parallel disks with suction and blowing

Basha

2020

Heat Trans

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In this research article, the electrically conducting magnetized radiative squeezed flow of two-dimensional time-dependent viscous incompressible flow between two parallel disks with heat source/sink and Joule heating effects under the presence of an unsteady homogeneous first order chemical reaction is demonstrated numerically. The considered physical problem is studied under the influence of Lorentz forces to describe the effect of an applied magnetic field. Heat dissipation due to viscosity and Joule heating are considered in the energy equation to demonstrate the behavior of the thermal profile. Also, the thermodynamic behavior of temperature field is described by considering the concept of heat source/sink in the energy equation. The mass transport characteristics of a viscous fluid are described through the time-dependent chemical reaction of first order type with homogenous behavior. Thus, the considered physical problem gives the time-dependent, highly nonlinear coupled partial differential equations, which are reduced to a system of ordinary differential equations by invoking the suitable similarity transformations. The discretized first order ordinary differential equations are solved by using the Runge-Kutta fourth order integration scheme with the

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Influence of inclined Lorentz forces through a porous media on squeezing Cu-H₂o nanofluid in the presence of heat source/sink

Cited by 18 publications

References 37 publications

Dynamics of liquid argon flow around carbon nanotube

Dynamics of liquid argon flow around carbon nanotube

Advances in Computational Fluid Mechanics in Cellular Flow Manipulation: A Review

A generalized perspective of magnetized radiative squeezed flow of viscous fluid between two parallel disks with suction and blowing

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