Structure and Dynamics of Water/Methanol Mixtures at Hydroxylated Silica Interfaces Relevant to Chromatography

Gupta, Prashant Kumar; Meuwly, Markus

doi:10.1002/cphc.201600180

Cited by 5 publications

(8 citation statements)

References 52 publications

(76 reference statements)

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“…Despite the superficially "simple" chemical composition of such systems, a molecular understanding underlying the separation process is challenging as the system is highly dynamical, heterogeneous and disordered. [235][236][237][238] Experimentally determined capacity factors which can be converted into retention times and free energies of binding are available for toluene, benzene, chlorobenzene, and phenol. 239 Using multipolar force fields that reproduce the hydration free energies for the probe molecules, 240…”

Section: Surface Reactionsmentioning

confidence: 99%

Quantitative Molecular Simulations

Töpfer,

Upadhyay,

Meuwly

2022

Preprint

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All-atom simulations can provide molecular-level insights into the dynamics of gasphase, condensed-phase and surface processes. One important requirement is a sufficiently realistic and detailed description of the underlying intermolecular interactions.The present perspective provides an overview of the present status of quantitative atomistic simulations from colleagues' and our own efforts for gas-and solution-phase processes and for the dynamics on surfaces. Particular attention is paid to direct comparison with experiment. An outlook discusses present challenges and future extensions to bring such dynamics simulations even closer to reality.

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Section: Surface Reactionsmentioning

confidence: 99%

Quantitative Molecular Simulations

Töpfer,

Upadhyay,

Meuwly

2022

Preprint

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“…As a result, the transport rate of its different components would be different, and this is the foundation of separation mechanisms in many devices such as liquid chromatography (LC), microfluidics, oil–water separation membranes, etc. In particular, nowadays, liquid chromatography (LC) has become a robust technology in the field of separation and chemical analysis, and as it is still evolving, it can achieve better performance or fulfill other special needs. − Liquid chromatography columns with various stationary phases (silica, alumina, titania) and mobile phases (water, − alcohols, ,,, nitriles, ,, cyclic hydrocarbons , ) are widely used in organic synthesis and pharmacology, extraction of natural products and drug discovery, clinical metabolomics, protein separation, food analysis, etc. Among them, liquid chromatography with silica as the stationary phase is the most widely used, such as hydroxylated silica in the normal-phase LC or silica-grafted with alkyl chains in reversed-phase LC.…”

Section: Introductionmentioning

confidence: 99%

Collective Solvation and Transport at Tetrahydrofuran–Silica Interfaces for Separation of Aromatic Compounds: Insight from Molecular Dynamics Simulations

2021

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We have performed umbrella sampling molecular dynamics simulations to study the separation mechanism of aromatic compounds at the tetrahydrofuran (THF)–methanol–silica interface by liquid chromatography. Solute molecules with different polarities (naphthol and naphthalene) are selected as representative aromatic compounds. For the polar solute (naphthol), the free energy profile shows a deep minimum near the THF–silica interface, suggesting strong interactions with the polar surface. When methanol is added to the interface, there is a sharp increase in naphthol’s free energy minimum, and the corresponding diffusion dynamics also undergoes a dramatic change. These findings explain the fast separation mechanism in recent experiments of separating fused ring compounds in asphaltenes with liquid chromatography. Further solvation structure and orientation analysis suggest that apolar and polar solutes may find their own comfort zones several angstroms away from the interface, and their phenyl ring’s orientations would undergo a parallel-to-perpendicular transition as the solute molecule moves away from the surface. Extending our simulation studies to systems with different solute concentrations reveals that there is a decrease in the adsorption free energy accompanied by enhanced surface diffusion as the solute concentration increases, which is related to the crowding in the interfacial layers. Our simulation analysis gives a detailed microscopic description of solute solvation and transport at the THF–silica chromatography interface and will be helpful for improving separation protocols in future applications.

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“…Solute retention in reversed-phase liquid chromatography is an important process dominated by intermolecular interactions and has received considerable attention during the past decade. [1][2][3][4][5][6][7][8] Due to the molecular complexity of the system and because QSAR (quantitative structure activity relationship)-like interpretations of experimental data remained largely inconclusive, it is of major importance to improve the understanding of solute retention using computational modelling so that the composition, functionalization and other physico-chemical properties of specific columns can be quantitatively predicted. [9][10][11] Extensions of molecularly-resolved pictures to the mesoscale for liquid chromatography are particularly relevant as they have the potential to reduce development times and potentially improved selectivity of such columns.…”

Section: Introductionmentioning

confidence: 99%

“…Despite the seemingly simple chemical composition of such systems, the atomistic understanding underlying the separation process remains elusive since the system is highly dynamical, heterogeneous and disordered [1][2][3][4] . Use of computational and experimental spectroscopic techniques such as IR [12][13][14] , Raman 15 and NMR [16][17][18] has provided important insights concerning the water/methanol mixture and proved to be useful in order to characterize these highly heterogeneous systems at the molecular level 1,7,[19][20][21][22][23] .…”

Section: Introductionmentioning

confidence: 99%

“…Recent work has shown that atomistic simulations with ac-curate force fields are suitable to quantitatively describe the thermodynamics of complex systems. 8,44,45 They allow to explicitly determine the hydration free energy 44,45 and the free energy of desorption from the surface 8 which can be directly compared with the experimentally measured partition coefficients k. 4,39 However, these force fields can be based on point charges (PC) or multipoles (MTP) depending on the molecules considered. 45 For the specific case of benzene derivative solutes, first a PC force field was used to model the entire system and then a combined PC/MTP force field, where only the solutes (here benzene derivatives) are treated with multipoles (in order to take into account the anisotropic electron distribution of the aromatic cycle and the moieties attached to it) while the chromatographic system is treated with PCs, and the resulting quantitative atomistic simulations were compared to experiment.…”

Section: Introductionmentioning

confidence: 99%

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From in silica to in silico: retention thermodynamics at solid–liquid interfaces

Hage

Bemish

Meuwly

2018

Phys. Chem. Chem. Phys.

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The dynamics of solvated molecules at the solid/liquid interface is essential for a molecular-level understanding for the solution thermodynamics in reversed phase liquid chromatography (RPLC). The heterogeneous nature of the systems and the competing intermolecular interactions makes solute retention in RPLC a surprisingly challenging problem which benefits greatly from modelling at atomistic resolution. However, the quality of the underlying computational model needs to be sufficiently accurate to provide a realistic description of the energetics and dynamics of systems, especially for solution-phase simulations. Here, the retention thermodynamics and the retention mechanism of a range of benzene-derivatives in C18 stationary-phase chains in contact with water/methanol mixtures is studied using point charge (PC) and multipole (MTP) electrostatic models. The results demonstrate that free energy simulations with a faithful MTP representation of the computational model provide quantitative and molecular level insight into the thermodynamics of adsorption/desorption in chromatographic systems while a conventional PC representation fails in doing so. This provides a rational basis to develop more quantitative and validated models for the optimization of separation systems.

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Structure and Dynamics of Water/Methanol Mixtures at Hydroxylated Silica Interfaces Relevant to Chromatography

Cited by 5 publications

References 52 publications

Quantitative Molecular Simulations

Quantitative Molecular Simulations

Collective Solvation and Transport at Tetrahydrofuran–Silica Interfaces for Separation of Aromatic Compounds: Insight from Molecular Dynamics Simulations

From in silica to in silico: retention thermodynamics at solid–liquid interfaces

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