Molecular Dynamics Simulations of Hydrophobic Nanoparticle Effects on Gas Hydrate Formation

Min, Jae; Kang, Dong Woo; Lee, Wonhyeong; Lee, Jae Woo

doi:10.1021/acs.jpcc.9b11459

Cited by 33 publications

(16 citation statements)

References 53 publications

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“…RNS-A has relatively good thermal conductivity and can remove heat more efficiently and faster. , Second, RNS-A with smaller particles can provide a larger gas–liquid contact surface area . Third, SiO 2 can also be the seeds of heterogeneous hydrate nucleation, providing nucleation sites, increasing the probability of nucleation, reducing the driving force required for the reaction, and shortening the induction time. ,− In addition, the Brownian motion of RNS-A and the stirring of the magnetic stirrer intensify the collision between RNS-A and destroy the bound water molecules on the surface . Moreover, Bai et al .…”

Section: Resultsmentioning

confidence: 99%

“…Nevertheless, the formation of gas hydrates is an exothermic process that causes temperatures to rise, thus reducing the driving force for hydrate formation. RNS-A has relatively good thermal conductivity and larger contact surface area, which can remove heat more efficiently and faster. ,, In addition, RNS-A can act as seeds of heterogeneous hydrate nucleation, providing nucleation sites, increasing the probability of nucleation, and enhancing the driving force to promote hydrate formation. − Meanwhile, the Brownian motion of RNS-A can reduce the film resistance at the gas–liquid interface and enhance the mass transfer effect. , In addition, the Brownian motion of RNS-A and the stirring of the magnetic stirrer destroy the bound water molecules on the surface, which promotes the hydrate formation.…”

Section: Resultsmentioning

confidence: 99%

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Experiment Investigation of SiO₂ Containing Amino Groups as a Kinetic Promoter for CO₂ Hydrates

Wang

2021

ACS Omega

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To diminish the greenhouse effect by reducing CO 2 emission into the air based on a capture and sequestration method through hydrates, the thermodynamic and kinetic effects of additives on CO 2 hydrate formation under 1.5 MPa in the presence of 5, 6, 8, 10, and 20 wt % RNS-A (reactive SiO 2 containing amino groups) were studied, and the stirrer speed was set to 800 rpm. This paper calculated the gas consumption and explained the possible mechanisms of RNS-A on CO 2 hydrates. The results showed that RNS-A was a kinetic additive instead of a thermodynamic one. It was found that 5−10 wt % RNS-A all shortened the induction time of hydrates, but only 5 and 6 wt % RNS-A increased the gas consumption of CO 2 hydrates. Although we observed the shortest induction time at a 10 wt % RNS-A system, the lowest gas consumption indicated its weak CO 2 capture and storage ability. In addition, when the concentration was 6 wt %, RNS-A had the highest gas consumption and its reaction time was relatively short. Considering the induction time and gas consumption, 6 wt % RNS-A was the optimal RNS-A concentration for CO 2 capture and sequestration, which was the most suitable for practical applications.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Experiment Investigation of SiO₂ Containing Amino Groups as a Kinetic Promoter for CO₂ Hydrates

Wang

2021

ACS Omega

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“…This study not only verified the promoting effect of nanoparticles on the formation and decomposition of CO 2 hydrate, but also tried to reveal the influence mechanism of nanoparticles on the formation and decomposition of CO 2 hydrate from the physicochemical level. Min et al 82 from J. W. Lee team of Korea Institute of advanced science and technology used molecular dynamics simulation (MDS) studied the effect of hydrophobic nanoparticles on the formation of CH 4 –THF binary hydrate. It was pointed out that the hydrate cell formed on the inner wall of hydrate provided heterogeneous station sites conducive to hydrate formation.…”

Section: Affecting Mechanism Of Nanoparticles On Hydrate Formationmentioning

confidence: 99%

Research progress on the effects of nanoparticles on gas hydrate formation

Zhang

et al. 2022

RSC Adv.

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“…[30] Contrary to standard DFT, MD simulations can occur at reasonable temperatures, instead of 0 K. There has been remarkable success in studying gas hydrates with MD in the past, with systems ranging in size from hundreds to millions of atoms. [28,52,[54][55][56][57][58][59] MD applies classical mechanics to atomic and molecular structures. The forces acting on all the atoms are calculated, and Newton's equations are solved to calculate how the molecules move.…”

Section: Molecular Dynamicsmentioning

confidence: 99%

Recent advances in density functional theory and molecular dynamics simulation of mechanical, interfacial, and thermal properties of natural gas hydrates in Canada

et al. 2022

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Gas hydrates are inclusion compounds of a water backbone that encloses gaseous molecules. Thanks to their applications in gas recovery, carbon capture and storage, gas storage, and flow assurance, generating high quality data and predictions of their properties is paramount. A review of novel techniques using first principles density functional theory and molecular dynamics simulations methods coupled to auxiliary simulations methods is presented herein.Structure I (sI), structure II (sII), and structure H (sH) hydrates have been studied extensively, with studies of their material strength showing that it is often misleading to use the properties of ice instead of the difficult-todetermine gas hydrate properties. Key differences between the three structures and their possible guests are presented. The interfacial properties of gas hydrates display key behaviours that control nucleation and growth, which are important phases in controlling and monitoring their formation. Gas hydrate thermal properties are also examined, with key differences existing between guests and some unusual alignment in the cages shown for carbon dioxide, ethane, and ethylene oxide sI hydrates. First principles infrared spectroscopy is also examined, with techniques showing that these signatures can be tied to and predict material properties to improve the speed of analysis. Therefore, by quantifying, modelling, predicting, and explaining their formation and dissociation, and linking these to their thermal, material, and interfacial properties, a database of reliable data for science and engineering methods and applications is formed to provide a basis for further work.

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Molecular Dynamics Simulations of Hydrophobic Nanoparticle Effects on Gas Hydrate Formation

Cited by 33 publications

References 53 publications

Experiment Investigation of SiO₂ Containing Amino Groups as a Kinetic Promoter for CO₂ Hydrates

Experiment Investigation of SiO₂ Containing Amino Groups as a Kinetic Promoter for CO₂ Hydrates

Research progress on the effects of nanoparticles on gas hydrate formation

Recent advances in density functional theory and molecular dynamics simulation of mechanical, interfacial, and thermal properties of natural gas hydrates in Canada

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Molecular Dynamics Simulations of Hydrophobic Nanoparticle Effects on Gas Hydrate Formation

Cited by 33 publications

References 53 publications

Experiment Investigation of SiO2 Containing Amino Groups as a Kinetic Promoter for CO2 Hydrates

Experiment Investigation of SiO2 Containing Amino Groups as a Kinetic Promoter for CO2 Hydrates

Research progress on the effects of nanoparticles on gas hydrate formation

Recent advances in density functional theory and molecular dynamics simulation of mechanical, interfacial, and thermal properties of natural gas hydrates in Canada

Contact Info

Product

Resources

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Experiment Investigation of SiO₂ Containing Amino Groups as a Kinetic Promoter for CO₂ Hydrates

Experiment Investigation of SiO₂ Containing Amino Groups as a Kinetic Promoter for CO₂ Hydrates