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The effect of the initial temperature, pressure, and shape of carbon nanopores on the separation process of SiO2 molecules from water vapor by molecular dynamics simulation

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dc.contributor.authorMei, Bing
dc.contributor.authorJasim, Dehyaa J.
dc.contributor.authorAlizadeh, As'ad
dc.contributor.authorHekmatifar, Maboud
dc.contributor.authorNasajpour-Esfahani, Navid
dc.contributor.authorSalahshour, Soheil
dc.contributor.authorSabetvand, Roozbeh
dc.contributor.authorToghraie, Davood
dc.contributor.institutionMei, Bing, College of Construction Engineering, Yunnan Agricultural University, Kunming, China
dc.contributor.institutionJasim, Dehyaa J., Department of Petroleum Engineering, Al-Amarah University College, Amarah, Iraq
dc.contributor.institutionAlizadeh, As'ad, Department of Civil Engineering, Cihan University-Erbil, Erbil, Iraq
dc.contributor.institutionHekmatifar, Maboud, Department of Mechanical Engineering, Islamic Azad University, Tehran, Iran
dc.contributor.institutionNasajpour-Esfahani, Navid, College of Engineering, Atlanta, United States
dc.contributor.institutionSalahshour, Soheil, Faculty of Engineering and Natural Sciences, Istanbul Okan University, Tuzla, Turkey, Faculty of Engineering and Natural Sciences, Bahçeşehir Üniversitesi, Istanbul, Turkey, Department of Mathematics and Computer Science, Lebanese American University, Beirut, Lebanon
dc.contributor.institutionSabetvand, Roozbeh, Department of Energy Engineering and Physics, Amirkabir University of Technology, Tehran, Iran
dc.contributor.institutionToghraie, Davood, Department of Mechanical Engineering, Islamic Azad University, Tehran, Iran
dc.date.accessioned2025-10-05T14:51:31Z
dc.date.issued2024
dc.description.abstractToday, with the advancement of science in nanotechnology, it is possible to remove dust nanostructures from the air breathed by humans or other fluids. In the present study, the separation of SiO<inf>2</inf> molecules from H<inf>2</inf>O vapor is studied using molecular dynamics (MD) simulation. This research studied the effect of initial temperature, nanopore geometry, and initial pressure on the separation of SiO<inf>2</inf> molecules. The obtained results show that by increasing the temperature to 500 K, the maximum velocity (Max-Vel) of the samples reached 2.47 Å/fs. Regarding the increasing velocity of particles, more particles pass via the nanopores. Moreover, the shape of the nanopore could affect the number of passing particles. The results show that in the samples with a cylindrical nanopore, 20 and 40% of SiO<inf>2</inf> molecules, and with the sphere cavity, about 32 and 38% of SiO<inf>2</inf> particles passed in the simulated structure. So, it can be concluded that the performance of carbon nanosheets with a cylindrical pore and 450 K was more optimal. Also, the results show that an increase in initial pressure leads to a decrease in the passage of SiO<inf>2</inf> particles. The results reveal that about 14 and 54% of Silica particles passed via the carbon membrane with increasing pressure. Therefore, for use in industry, in terms of separating dust particles, in addition to applying an EF, temperature, nanopore geometry, and initial pressure should be controlled. © 2024 Elsevier B.V., All rights reserved.
dc.identifier.doi10.1016/j.chemosphere.2023.140966
dc.identifier.issn00456535
dc.identifier.issn18791298
dc.identifier.pubmed38109972
dc.identifier.scopus2-s2.0-85180401618
dc.identifier.urihttps://doi.org/10.1016/j.chemosphere.2023.140966
dc.identifier.urihttps://hdl.handle.net/20.500.14719/7374
dc.identifier.volume349
dc.language.isoen
dc.publisherElsevier Ltd
dc.relation.sourceChemosphere
dc.subject.authorkeywordsMolecular Dynamics Simulation
dc.subject.authorkeywordsNanopores
dc.subject.authorkeywordsSeparation
dc.subject.authorkeywordsSio2 Molecules
dc.subject.authorkeywordsCarbon
dc.subject.authorkeywordsSilicon Dioxide
dc.subject.authorkeywordsWater
dc.subject.authorkeywordsCarbon
dc.subject.authorkeywordsDust
dc.subject.authorkeywordsSilicon Dioxide
dc.subject.authorkeywordsSteam
dc.subject.authorkeywordsAir
dc.subject.authorkeywordsCarbon
dc.subject.authorkeywordsDust
dc.subject.authorkeywordsMolecular Dynamics
dc.subject.authorkeywordsMolecules
dc.subject.authorkeywordsNanopores
dc.subject.authorkeywordsPressure Effects
dc.subject.authorkeywordsSilicon
dc.subject.authorkeywordsCarbon Nanopores
dc.subject.authorkeywordsDynamics Simulation
dc.subject.authorkeywordsInitial Pressure
dc.subject.authorkeywordsInitial Shape
dc.subject.authorkeywordsInitial Temperatures
dc.subject.authorkeywordsMolecular Dynamic Simulation
dc.subject.authorkeywordsSeparation Process
dc.subject.authorkeywordsSio2 Molecule
dc.subject.authorkeywordsTemperature Shape
dc.subject.authorkeywordsWater Vapour
dc.subject.authorkeywordsSilica
dc.subject.authorkeywordsCarbon
dc.subject.authorkeywordsNanomaterial
dc.subject.authorkeywordsNanosheet
dc.subject.authorkeywordsSilicon Dioxide
dc.subject.authorkeywordsWater
dc.subject.authorkeywordsCarbon Nanotube
dc.subject.authorkeywordsMolecular Analysis
dc.subject.authorkeywordsSeparation
dc.subject.authorkeywordsSilica
dc.subject.authorkeywordsSimulation
dc.subject.authorkeywordsTemperature Effect
dc.subject.authorkeywordsWater Vapor
dc.subject.authorkeywordsArticle
dc.subject.authorkeywordsControlled Study
dc.subject.authorkeywordsElectric Field
dc.subject.authorkeywordsGeometry
dc.subject.authorkeywordsHuman
dc.subject.authorkeywordsMolecular Dynamics
dc.subject.authorkeywordsRight To Freedom Of Movement
dc.subject.authorkeywordsTemperature
dc.subject.authorkeywordsVelocity
dc.subject.authorkeywordsDust
dc.subject.authorkeywordsHumans
dc.subject.authorkeywordsMolecular Dynamics Simulation
dc.subject.authorkeywordsSilicon Dioxide
dc.subject.authorkeywordsSteam
dc.subject.authorkeywordsTemperature
dc.subject.indexkeywordsAir
dc.subject.indexkeywordsCarbon
dc.subject.indexkeywordsDust
dc.subject.indexkeywordsMolecular dynamics
dc.subject.indexkeywordsMolecules
dc.subject.indexkeywordsNanopores
dc.subject.indexkeywordsPressure effects
dc.subject.indexkeywordsSilicon
dc.subject.indexkeywordsCarbon nanopores
dc.subject.indexkeywordsDynamics simulation
dc.subject.indexkeywordsInitial pressure
dc.subject.indexkeywordsInitial shape
dc.subject.indexkeywordsInitial temperatures
dc.subject.indexkeywordsMolecular dynamic simulation
dc.subject.indexkeywordsSeparation process
dc.subject.indexkeywordsSiO2 molecule
dc.subject.indexkeywordsTemperature shape
dc.subject.indexkeywordsWater vapour
dc.subject.indexkeywordsSilica
dc.subject.indexkeywordscarbon
dc.subject.indexkeywordsnanomaterial
dc.subject.indexkeywordsnanosheet
dc.subject.indexkeywordssilicon dioxide
dc.subject.indexkeywordswater
dc.subject.indexkeywordscarbon nanotube
dc.subject.indexkeywordsmolecular analysis
dc.subject.indexkeywordsseparation
dc.subject.indexkeywordssilica
dc.subject.indexkeywordssimulation
dc.subject.indexkeywordstemperature effect
dc.subject.indexkeywordswater vapor
dc.subject.indexkeywordsArticle
dc.subject.indexkeywordscontrolled study
dc.subject.indexkeywordselectric field
dc.subject.indexkeywordsgeometry
dc.subject.indexkeywordshuman
dc.subject.indexkeywordsmolecular dynamics
dc.subject.indexkeywordsright to freedom of movement
dc.subject.indexkeywordstemperature
dc.subject.indexkeywordsvelocity
dc.subject.indexkeywordsdust
dc.subject.indexkeywordsHumans
dc.subject.indexkeywordsMolecular Dynamics Simulation
dc.subject.indexkeywordsSilicon Dioxide
dc.subject.indexkeywordsSteam
dc.subject.indexkeywordsTemperature
dc.titleThe effect of the initial temperature, pressure, and shape of carbon nanopores on the separation process of SiO2 molecules from water vapor by molecular dynamics simulation
dc.typeArticle
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dspace.entity.typePublication
local.indexed.atScopus
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person.identifier.scopus-author-id56999952800
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person.identifier.scopus-author-id23028598900
person.identifier.scopus-author-id57211635487
person.identifier.scopus-author-id36807246100

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