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323 results on '"Moultos, Othonas A."'

1. Effect of dissolved KOH and NaCl on the solubility of water in hydrogen: A Monte Carlo simulation study.

Author

Habibi, Parsa, Dey, Poulumi, Vlugt, Thijs J. H., and Moultos, Othonas A.

Subjects
SATURATION vapor pressure, ELECTROLYTE solutions, MONTE Carlo method, AQUEOUS electrolytes, EQUATIONS of state
Abstract

Vapor–Liquid Equilibria (VLE) of hydrogen (H2) and aqueous electrolyte (KOH and NaCl) solutions are central to numerous industrial applications such as alkaline electrolysis and underground hydrogen storage. Continuous fractional component Monte Carlo simulations are performed to compute the VLE of H2 and aqueous electrolyte solutions at 298–423 K, 10–400 bar, 0–8 mol KOH/kg water, and 0–6 mol NaCl/kg water. The densities and activities of water in aqueous KOH and NaCl solutions are accurately modeled (within 2% deviation from experiments) using the non-polarizable Madrid-2019 Na+/Cl ion force fields for NaCl and the Madrid-Transport K+ and Delft Force Field of OH for KOH, combined with the TIP4P/2005 water force field. A free energy correction (independent of pressure, salt type, and salt molality) is applied to the computed infinite dilution excess chemical potentials of H2 and water, resulting in accurate predictions (within 5% of experiments) for the solubilities of H2 in water and the saturated vapor pressures of water for a temperature range of 298–363 K. The compositions of water and H2 are computed using an iterative scheme from the liquid phase excess chemical potentials and densities, in which the gas phase fugacities are computed using the GERG-2008 equation of state. For the first time, the VLE of H2 and aqueous KOH/NaCl systems are accurately captured with respect to experiments (i.e., for both the liquid and gas phase compositions) without compromising the liquid phase properties or performing any refitting of force fields. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Ultrasound enhanced diffusion in hydrogels: An experimental and non-equilibrium molecular dynamics study.

Author

Price, Sebastian E. N., Einen, Caroline, Moultos, Othonas A., Vlugt, Thijs J. H., Davies, Catharina de Lange, Eiser, Erika, and Lervik, Anders

Subjects
MOLECULAR dynamics, ULTRASONIC imaging, HEAT equation, RANDOM walks, DIFFUSION coefficients, HYDROGELS, NON-equilibrium reactions
Abstract

Focused ultrasound has experimentally been found to enhance the diffusion of nanoparticles; our aim with this work is to study this effect closer using both experiments and non-equilibrium molecular dynamics. Measurements from single particle tracking of 40 nm polystyrene nanoparticles in an agarose hydrogel with and without focused ultrasound are presented and compared with a previous experimental study using 100 nm polystyrene nanoparticles. In both cases, we observed an increase in the mean square displacement during focused ultrasound treatment. We developed a coarse-grained non-equilibrium molecular dynamics model with an implicit solvent to investigate the increase in the mean square displacement and its frequency and amplitude dependencies. This model consists of polymer fibers and two sizes of nanoparticles, and the effect of the focused ultrasound was modeled as an external oscillating force field. A comparison between the simulation and experimental results shows similar mean square displacement trends, suggesting that the particle velocity is a significant contributor to the observed ultrasound-enhanced mean square displacement. The resulting diffusion coefficients from the model are compared to the diffusion equation for a two-time continuous time random walk. The model is found to have the same frequency dependency. At lower particle velocity amplitude values, the model has a quadratic relation with the particle velocity amplitude as described by the two-time continuous time random walk derived diffusion equation, but at higher amplitudes, the model deviates, and its diffusion coefficient reaches the non-hindered diffusion coefficient. This observation suggests that at higher ultrasound intensities in hydrogels, the non-hindered diffusion coefficient can be used. [ABSTRACT FROM AUTHOR]

Published
2024
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17. Molecular Insights into the Microscopic Behavior of CO2Hydrates in Oceanic Sediments: Implications for Carbon Sequestration

Author

Mi, Fengyi, Li, Wei, Pang, Jiangtao, Moultos, Othonas A., Ning, Fulong, and Vlugt, Thijs J.H.

Abstract

Knowledge of the microscopic behavior of CO2hydrates in oceanic sediments is crucial to evaluate the efficiency and stability of hydrate-based CO2sequestration in oceans. Here, systematic molecular dynamics simulations are executed to investigate the growth and dissociation of CO2hydrates, and the mechanical instability of CO2hydrate-Illite interface in the brine-urea-Illite system. Simulation results show that the CO2hydrate growth is jointly affected by the confined space, Illite surface properties, and presence of urea. Specifically, the interfacial H2O and the ion layer on the Illite surface hinder the growth of CO2hydrate crystals toward Illite surfaces. Urea molecules can bind salt ions and increase CO2concentrations in the water, thus kinetically promoting CO2hydrate growth. The dissociation of the CO2hydrate is affected by Illite surface properties and the CO2hydrate structure. CO2hydrate starts from the regions where hydrate particles are minimally in contact and extends on both sides. The mechanical tension and compression of the CO2hydrate-Illite interface exhibit nonlinear characteristics by changing the hydrogen bonds and the CO2hydrate structure. The molecular insight into the microscopic behavior of CO2hydrates in the brine-urea-Illite system contributes to a broader understanding of hydrate-based CO2sequestration.

Published
2024
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18. Diffusivity of CO2in H2O: A Review of Experimental Studies and Molecular Simulations in the Bulk and in Confinement

Author

Polat, H. Mert, Coelho, Felipe M., Vlugt, Thijs J. H., Mercier Franco, Luís Fernando, Tsimpanogiannis, Ioannis N., and Moultos, Othonas A.

Abstract

An in-depth review of the available experimental and molecular simulation studies of CO2diffusion in H2O, which is a central property in important industrial and environmental processes, such as carbon capture and storage, enhanced oil recovery, and in the food industry is presented. The cases of both bulk and confined systems are covered. The experimental and molecular simulation data gathered are analyzed, and simple and computationally efficient correlations are devised. These correlations are applicable to conditions from 273 K and 0.1 MPa up to 473 K and 45 MPa. The available experimental data for diffusion coefficients of CO2in brines are also collected, and their dependency on temperature, pressure, and salinity is examined in detail. Other engineering models and correlations reported in literature are also presented. The review of the simulation studies focuses on the force field combinations, the data for diffusivities at low and high pressures, finite-size effects, and the correlations developed based on the Molecular Dynamics data. Regarding the confined systems, we review the main methods to measure and compute the diffusivity of confined CO2and discuss the main natural and artificial confining media (i.e., smectites, calcites, silica, MOFs, and carbon materials). Detailed discussion is provided regarding the driving force for diffusion of CO2and H2O under confinement, and on the role of effects such as H2O adsorption on hydrophilic confining media on the diffusivity of CO2. Finally, an outlook of future research paths for advancing the field of CO2diffusivity in H2O at the bulk phase and in confinement is laid out.

Published
2024
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27. A review on nature-inspired gating membranes: From concept to design and applications.

Author

Bazyar, Hanieh, Moultos, Othonas A., and Lammertink, Rob G. H.

Subjects
*ION channels, *EAST Indian lotus, *LIQUID membranes, *SUPERHYDROPHOBIC surfaces, *PITCHER plants, *BIOLOGICAL systems, *WETTING
Abstract

Nature has been a constant source of inspiration for technological developments. Recently, the study of nature-inspired materials has expanded to the micro- and nanoscale, facilitating new breakthroughs in the design of materials with unique properties. Various types of superhydrophobic surfaces inspired by the lotus/rice leaf are examples of nature-inspired surfaces with special wettability properties. A new class of functional surfaces whose design is inspired by the pitcher plant are the slippery liquid-infused porous surfaces (SLIPS). This Review summarizes the properties, design criteria, fabrication strategies, and working mechanisms of both surfaces with specific focus on SLIPS. The applications of SLIPS in the field of membrane technology [slippery liquid-infused membranes (SLIMs)] are also reviewed. These membranes are also known as liquid gating membranes due to the gating functionality of the capillary-stabilized liquid in the membrane pores leading to a smart gating mechanism. Similar to the gating ion channels in biological systems, the pores open and close in response to the ambient stimuli, e.g., pressure, temperature, and ions. Different types of stimuli-responsive smart gating membranes are introduced here, and their properties and applications are reviewed in detail. Finally, challenges and perspectives on both SLIPS and smart gating membranes are discussed. This Review provides a thorough discussion and practical applications of nature-inspired functional surfaces and membranes to pave the way for future research and further developments in this emerging field. [ABSTRACT FROM AUTHOR]

Published
2022
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36. Vapor pressures and vapor phase compositions of choline chloride urea and choline chloride ethylene glycol deep eutectic solvents from molecular simulation.

Author

Salehi, Hirad S., Polat, H. Mert, de Meyer, Frédérick, Houriez, Céline, Coquelet, Christophe, Vlugt, Thijs J. H., and Moultos, Othonas A.

Subjects
CHOLINE chloride, EUTECTICS, VAPOR pressure, ETHYLENE glycol, ETHYLENE dichloride, MONTE Carlo method, ACTIVITY coefficients
Abstract

Despite the widespread acknowledgment that deep eutectic solvents (DESs) have negligible vapor pressures, very few studies in which the vapor pressures of these solvents are measured or computed are available. Similarly, the vapor phase composition is known for only a few DESs. In this study, for the first time, the vapor pressures and vapor phase compositions of choline chloride urea (ChClU) and choline chloride ethylene glycol (ChClEg) DESs are computed using Monte Carlo simulations. The partial pressures of the DES components were obtained from liquid and vapor phase excess Gibbs energies, computed using thermodynamic integration. The enthalpies of vaporization were computed from the obtained vapor pressures, and the results were in reasonable agreement with the few available experimental data in the literature. It was found that the vapor phases of both DESs were dominated by the most volatile component (hydrogen bond donor, HBD, i.e., urea or ethylene glycol), i.e., 100% HBD in ChClEg and 88%–93% HBD in ChClU. Higher vapor pressures were observed for ChClEg compared to ChClU due to the higher volatility of ethylene glycol compared to urea. The influence of the liquid composition of the DESs on the computed properties was studied by considering different mole fractions (i.e., 0.6, 0.67, and 0.75) of the HBD. Except for the partial pressure of ethylene glycol in ChClEg, all the computed partial pressures and enthalpies of vaporization showed insensitivity toward the liquid composition. The activity coefficient of ethylene glycol in ChClEg was computed at different liquid phase mole fractions, showing negative deviations from Raoult's law. [ABSTRACT FROM AUTHOR]

Published
2021
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40. On the computation of electrical conductivities of aqueous electrolyte solutions: Two surfaces one property

Author

Blázquez Fernández, Samuel, Fernández Abascal, José Luis, Lagerweij, Jelle, Habibi, Parsa, Dey, Poloumy, Vlugt, Thijs, Moultos, Othonas, Vega De Las Heras, Carlos, Blázquez Fernández, Samuel, Fernández Abascal, José Luis, Lagerweij, Jelle, Habibi, Parsa, Dey, Poloumy, Vlugt, Thijs, Moultos, Othonas, and Vega De Las Heras, Carlos

Abstract

In this work, we have computed electrical conductivities at ambient conditions of aqueous NaCl and KCl solutions by using the Einstein-Helfand equation. Common force fields (charge q =±1 e) do not reproduce the experimental values of electrical conductivities, viscosities and diffusion coefficients. Recently, we proposed the idea of using different charges to describe the Potential Energy Surface (PES) and the Dipole Moment Surface (DMS). In this work, we implement this concept. The equilibrium trajectories required to evaluate electrical conductivities (within linear response theory) were obtained by using scaled charges (with the value q =±0.75 e) to describe the PES. The potential parameters were those of the Madrid-Transport force field, which describe accurately viscosities and diffusion coefficients of these ionic solutions. However, integer charges were used to compute the conductivities (thus describing the DMS). The basic idea is that although the scaled charge describes the ion-water interaction better, the integer charge reflects the value of the charge that is transported due to the electric field. The agreement obtained with experiments is excellent, as for the first time electrical conductivities (and the other transport properties) of NaCl and KCl electrolyte solutions are described with high accuracy for the whole concentration range up to their solubility limit. Finally, we propose an easy way to obtain a rough estimate of the actual electrical conductivity of the potential model under consideration using the approximate Nernst-Einstein equation, which neglects correlations between different ions., Depto. de Química Física, Fac. de Ciencias Químicas, TRUE, submitted

Published
2023

41. The dilatable membrane of oleosomes (lipid droplets) allows their in vitro resizing and triggered release of lipids

Author

Ntone, Eleni, Rosenbaum, Benjamin, Sridharan, Simha, Willems, Stan B.J., Moultos, Othonas A., Vlugt, Thijs J.H., Meinders, Marcel B.J., Sagis, Leonard M.C., Bitter, Johannes H., Nikiforidis, Constantinos V., Ntone, Eleni, Rosenbaum, Benjamin, Sridharan, Simha, Willems, Stan B.J., Moultos, Othonas A., Vlugt, Thijs J.H., Meinders, Marcel B.J., Sagis, Leonard M.C., Bitter, Johannes H., and Nikiforidis, Constantinos V.

Abstract

It has been reported that lipid droplets (LDs), called oleosomes, have an inherent ability to inflate or shrink when absorbing or fueling lipids in the cells, showing that their phospholipid/protein membrane is dilatable. This property is not that common for membranes stabilizing oil droplets and when well understood, it could be exploited for the design of responsive and metastable droplets. To investigate the nature of the dilatable properties of the oleosomes, we extracted them from rapeseeds to obtain an oil-in-water emulsion. Initially, we added an excess of rapeseed oil in the dispersion and applied high-pressure homogenization, resulting in a stable oil-in-water emulsion, showing the ability of the molecules on the oleosome membrane to rearrange and reach a new equilibrium when more surface was available. To confirm the rearrangement of the phospholipids on the droplet surface, we used molecular dynamics simulations and showed that the fatty acids of the phospholipids are solubilized in the oil core and are homogeneously spread on the liquid-like membrane, avoiding clustering with neighbouring phospholipids. The weak lateral interactions on the oleosome membrane were also confirmed experimentally, using interfacial rheology. Finally, to investigate whether the weak lateral interactions on the oleosome membrane can be used to have a triggered change of conformation by an external force, we placed the oleosomes on a solid hydrophobic surface and found that they destabilise, allowing the oil to leak out, probably due to a reorganisation of the membrane phospholipids after their interaction with the hydrophobic surface. The weak lateral interactions on the LD membrane and their triggered destabilisation present a unique property that can be used for a targeted release in foods, pharmaceuticals and cosmetics.

Published
2023

43. Predictive model for the intra-diffusion coefficients of H2 and O2 in vapour H2O based on data from molecular dynamics simulations.

Author

Moultos, Othonas A. and Tsimpanogiannis, Ioannis N.

Subjects
*MOLECULAR dynamics, *VAPORS, *PREDICTION models, *STATISTICAL correlation
Abstract

Available data from experiments and molecular simulations for the intra-diffusivities of H 2 and O 2 in H 2 O, and for the self-diffusivity of pure H 2 O (at pressure and temperature conditions in which the solvent is in the vapour phase) are compared against calculations based on the Chapman-Enskog theory or other semi-empirical/semi-theoretical methods. A novel methodology is proposed to extrapolate the intra-/self-diffusivities data computed from molecular dynamics simulations at low pressures. The extrapolated values are used to further refine the recently-proposed [Tsimpanogiannis et al., J. Chem. Eng. Data, 66, 3226-3244, (2021)], molecular simulation based correlation of intra-/self-diffusivities as a function of pressure and temperature with the solvent being in the vapour phase. [ABSTRACT FROM AUTHOR]

Published
2023
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44. The Dilatable Interface of Oleosomes (Lipid Droplets) Allows Their Inflation and Shrinkage During Loading and Releasing of Lipids

Author

Ntone, Eleni, primary, Rosenbaum, Benjamin, additional, Sridharan, Simha, additional, Willems, Stan B.J., additional, Moultos, Othonas A., additional, Vlugt, Thijs J. H., additional, Meinders, Marcel B.J., additional, Sagis, Leonard M.C., additional, Bitter, Johannes H., additional, and Nikiforidis, Costantinos V., additional

Published
2023
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45. The Paramount Synergy between Multi-Scale Thermodynamics to Describe the Singular Behaviour of Fast Reacting Binary Mixtures in Vapour-Liquid Equilibrium

Author

Lasala, Silvia, primary, Samukov, Konstantin, additional, Polat, Mert, additional, Lachet, Véronique, additional, Herbinet, Olivier, additional, Privat, Romain, additional, Jaubert, Jean-Noel, additional, Moultos, Othonas A., additional, De Ras, Kevin, additional, and Vlugt, Thijs J. H., additional

Published
2023
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47. How sensitive are physical properties of choline chloride–urea mixtures to composition changes: Molecular dynamics simulations and Kirkwood–Buff theory.

Author

Celebi, Alper T., Dawass, Noura, Moultos, Othonas A., and Vlugt, Thijs J. H.

Subjects
RADIAL distribution function, MOLECULAR dynamics, MATERIALS science, IONIC conductivity, MOLE fraction, CHOLINE
Abstract

Deep eutectic solvents (DESs) have emerged as a cheaper and greener alternative to conventional organic solvents. Choline chloride (ChCl) mixed with urea at a molar ratio of 1:2 is one of the most common DESs for a wide range of applications such as electrochemistry, material science, and biochemistry. In this study, molecular dynamics simulations are performed to study the effect of urea content on the thermodynamic and transport properties of ChCl and urea mixtures. With increased mole fraction of urea, the number of hydrogen bonds (HBs) between cation–anion and ion–urea decreases, while the number of HBs between urea–urea increases. Radial distribution functions (RDFs) for ChCl–urea and ChCl–ChCl pairs shows a significant decrease as the mole fraction of urea increases. Using the computed RDFs, Kirkwood–Buff Integrals (KBIs) are computed. KBIs show that interactions of urea–urea become stronger, while interactions of urea–ChCl and ChCl–ChCl pairs become slightly weaker with increasing mole fraction of urea. All thermodynamic factors are found larger than one, indicating a non-ideal mixture. Our results also show that self- and collective diffusivities increase, while viscosities decrease with increasing urea content. This is mainly due to the weaker interactions between ions and urea, resulting in enhanced mobilities. Ionic conductivities exhibit a non-monotonic behavior. Up to a mole fraction of 0.5, the ionic conductivities increase with increasing urea content and then reach a plateau. [ABSTRACT FROM AUTHOR]

Published
2021
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48. Thermodynamic, transport, and structural properties of hydrophobic deep eutectic solvents composed of tetraalkylammonium chloride and decanoic acid.

Author

S. Salehi, Hirad, Celebi, Alper T., Vlugt, Thijs J. H., and Moultos, Othonas A.

Subjects
EUTECTICS, DECANOIC acid, ACYL chlorides, RADIAL distribution function, TETRAALKYLAMMONIUM, HYDROGEN bonding
Abstract

With the emergence of hydrophobic deep eutectic solvents (DESs), the scope of applications of DESs has been expanded to include situations in which miscibility with water is undesirable. Whereas most studies have focused on the applications of hydrophobic DESs from a practical standpoint, few theoretical works exist that investigate the structural and thermodynamic properties at the nanoscale. In this study, Molecular Dynamics (MD) simulations have been performed to model DESs composed of tetraalkylammonium chloride hydrogen bond acceptor and decanoic acid hydrogen bond donor (HBD) at a molar ratio of 1:2, with three different cation chain lengths (4, 7, and 8). After fine-tuning force field parameters, densities, viscosities, self-diffusivities, and ionic conductivities of the DESs were computed over a wide temperature range. The liquid structure was examined using radial distribution functions (RDFs) and hydrogen bond analysis. The MD simulations reproduced the experimental density and viscosity data from the literature reasonably well and were used to predict diffusivities and ionic conductivities, for which experimental data are scarce or unavailable. It was found that although an increase in the cation chain length considerably affected the density and transport properties of the DESs (i.e., yielding smaller densities and slower dynamics), no significant influence was observed on the RDFs and the hydrogen bonds. The self-diffusivities showed the following order for the mobility of the various components: HBD > anion > cation. Strong hydrogen bonds between the hydroxyl and carbonyl groups of decanoic acid and between the hydroxyl group of decanoic acid and chloride were observed to dominate the intermolecular interactions. [ABSTRACT FROM AUTHOR]

Published
2021
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