Interpretation of Chromatographic Retention Based on Electrostatic Theories

Okada, Tetsuo

doi:10.2116/analsci.14.469

Cited by 10 publications

(6 citation statements)

References 64 publications

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“…Ion permeation across the cell membrane is tightly controlled by specialized proteins called ion channels [232-234]. In physical chemistry, ion solvation is also important in several processes such as chemical purification [235] and chromatographic systems [236] and ion-specific chelators [237]. …”

Section: Application Of Polarizable Force Fieldsmentioning

confidence: 99%

Molecular modeling and dynamics studies with explicit inclusion of electronic polarizability: theory and applications

2009

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A current emphasis in empirical force fields is on the development of potential functions that explicitly treat electronic polarizability. In the present article, the commonly used methodologies for modelling electronic polarization are presented along with an overview of selected application studies. Models presented include induced point-dipoles, classical Drude oscillators, and fluctuating charge methods. The theoretical background of each method is followed by an introduction to extended Langrangian integrators required for computationally tractable molecular dynamics simulations using polarizable force fields. The remainder of the review focuses on application studies using these methods. Emphasis is placed on water models, for which numerous examples exist, with a more thorough discussion presented on the recently published models associated with the Drudebased CHARMM and the AMOEBA force fields. The utility of polarizable models for the study of ion solvation is then presented followed by an overview of studies of small molecules (e.g. CCl 4 , alkanes, etc) and macromolecule (proteins, nucleic acids and lipid bilayers) application studies. The review is written with the goal of providing a general overview of the current status of the field and to facilitate future application and developments.

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Section: Application Of Polarizable Force Fieldsmentioning

confidence: 99%

Molecular modeling and dynamics studies with explicit inclusion of electronic polarizability: theory and applications

2009

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“…For example, the transfer of ions between media obviously plays a critical role in the design of effective ion-exchange resins, used in chemical purification . A detailed understanding of the interactions of ions in solution is a major contributor to the understanding of selectivity and separation in chromatographic systems …”

Section: Introductionmentioning

confidence: 99%

Ion Solvation Thermodynamics from Simulation with a Polarizable Force Field

2003

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Thermodynamic measurements of the solvation of salts and electrolytes are relatively straightforward, but it is not possible to separate total solvation free energies into distinct cation and anion contributions without reference to an additional extrathermodynamic assumption. The present work attempts to resolve this difficulty using molecular dynamics simulations with the AMOEBA polarizable force field and perturbation techniques to directly compute absolute solvation free energies for potassium, sodium, and chloride ions in liquid water and formamide. Corresponding calculations are also performed with two widely used nonpolarizable force fields. The simulations with the polarizable force field accurately reproduce in vacuo quantum mechanical results, experimental ion-cluster solvation enthalpies, and experimental solvation free energies for whole salts, while the other force fields do not. The results indicate that calculations with a polarizable force field can capture the thermodynamics of ion solvation and that the solvation free energies of the individual ions differ by several kilocalories from commonly cited values.

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“…The potential change of the polyelectrolytes upon the addition of charged species can be attributed to two possible factors: the shrinkage of the electric double layer (EDL) and charge cancellation by electrostatic adsorption on the charged surface. − For colloidal particles, their surface potential, Ψ, and surface charge density, σ, have the relationship as expressed in eq normalΨ = σ ε 0 ε κ ( 1 + 1 κ a ) where ε 0 is the vacuum dielectric constant, ε is the relative dielectric constant, and κ is the inverse of the Debye length expressed as κ = 2000 z 2 e 2 N A C ε 0 ε k T where z is the valence of the coexisting ion, e is the elementary charge, N A is Avogadro’s number, C is the ion concentration, k is the Boltzmann constant, and T is the absolute temperature . If there is no adsorption on the surface to change the surface charge density at the polymer surface, σ d can be considered to be constant throughout the experiment because the amount of counterions to cancel the polymer surface charges should be constant to neutralize the entire solution.…”

Section: Resultsmentioning

confidence: 99%

Charge-Selective Aggregation Behavior of Thermoresponsive Polyelectrolytes Having Low Charge Density in Aqueous Solutions of Organic Counterions

2023

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The aggregation behavior of thermoresponsive polyelectrolytes with low charge density in aqueous solutions of organic counterions was investigated. We synthesized two thermoresponsive polyelectrolytes: anionic poly(N-isopropylacrylamide-co-(3-sulfopropyl)acrylamide potassium) (P-NIP-SPAK) and cationic poly(N-isopropylacrylamide-co-(3-acrylamidepropyl)trimethylammonium chloride) (P-NIP-AAPTAC). The polyelectrolytes remained soluble in their aqueous solutions even above the lower critical soluble temperature of P-NIP owing to the strong hydration property of the ionic groups. The aggregation occurred when organic counterions were added to the solution. In these solution systems, the concentration of counterions exceeds those of ionic groups introduced into the polyelectrolytes. The aggregation behavior is attributed to the salting-out effect of counterions accommodated near the polyelectrolyte surface by electrostatic interaction. This aggregation behavior was utilized for the charge-selective recognition of amino acids. P-NIP-SPAK aggregated only when basic amino acids were added under acidic conditions, whereas P-NIP-AAPTAC aggregated only when acidic amino acids were added under basic conditions. The results herein demonstrate that P-NIP-SPAK and P-NIP-AAPTAC have the potential to be used as charge-selective polymer sensors for amino acids without having to strictly control the experimental conditions.

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Interpretation of Chromatographic Retention Based on Electrostatic Theories

Cited by 10 publications

References 64 publications

Molecular modeling and dynamics studies with explicit inclusion of electronic polarizability: theory and applications

Molecular modeling and dynamics studies with explicit inclusion of electronic polarizability: theory and applications

Ion Solvation Thermodynamics from Simulation with a Polarizable Force Field

Charge-Selective Aggregation Behavior of Thermoresponsive Polyelectrolytes Having Low Charge Density in Aqueous Solutions of Organic Counterions

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