Influence of Explicit Ions on Titration Curves and Conformations of Flexible Polyelectrolytes: A Monte Carlo Study

Carnal, Fabrice; Ulrich, Serge; Stoll, Serge

doi:10.1021/ma901909b

Cited by 34 publications

(36 citation statements)

References 58 publications

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“…At a chosen α , it would clearly cost more energy to increase ionization of a longer chain due to the higher number of vicinal charges. As for the qualitative behavior of

α (pH ‐ p K_{normala})

curves, it agrees nicely with what published in the literature so far, albeit the ionization degree tends to be slightly higher at a chosen pH‐p K a due to the extendible bonds.…”

Section: Resultssupporting

confidence: 89%

“…In this respect, we opted for using an extension of the titrable linear spring‐charged bead model proposed by Åkesson et al, introducing a short range many‐body interaction between conjugated acid–base pair that limits the number of cH‐Bond per charged group ( vide infra see Polyelectrolyte Models section). To quantitatively gauge the effect of such interaction on polyelectrolyte properties, titration experiments can be simulated as suggested in the literature varying the parameters that define the model. Particularly, we investigated the impact of the many‐body interaction strength and the maximum number of cH‐Bonds allowed.…”

Section: Introductionmentioning

confidence: 99%

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Influence of charged intramolecular hydrogen bonds in weak polyelectrolytes: A Monte Carlo study of flexible and extendible polymeric chains in solution and near charged spheres

Mella

Mollica

Izzo

2015

J. Polym. Sci. Part B: Polym. Phys.

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For weak polyelectrolytes, the interplay between pH, solvent properties, and polymer structure affects the amount of charges, their distribution, and hence their conformations via Coloumb repulsion. Attractive interactions can also develop between charged and neutral sites counteracting the expected Coulomb-induced expansion. To gauge how such competition affects polyelectrolyte structure and ionization, the titration of a single polyelectrolyte chain, isolated or close to a charged sphere, mimicked with a novel many-body potential model is simulated with Monte Carlo. Apart from showing a 10-fold higher ionization than isolated monomers at low pH, interacting species contracted forming short-range clusters of charged and neutral ionizable groups. The presence of a charged sphere synergically boosted both effects due to monomer interactions, forcing the chains to condense onto its surface at much lower pH. Structural properties, however, seem to be controlled only by the ionization degree despite the presence of the topological restraint represented by the spherical surface. Using Monte Carlo titration results, the equilibrium ionization of isolated chains is also estimated; the results evidence that even weak interactions can easily lead to a doubling of the total charg

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“…At a chosen α , it would clearly cost more energy to increase ionization of a longer chain due to the higher number of vicinal charges. As for the qualitative behavior of

α (pH ‐ p K_{normala})

curves, it agrees nicely with what published in the literature so far, albeit the ionization degree tends to be slightly higher at a chosen pH‐p K a due to the extendible bonds.…”

Section: Resultssupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Influence of charged intramolecular hydrogen bonds in weak polyelectrolytes: A Monte Carlo study of flexible and extendible polymeric chains in solution and near charged spheres

Mella

Mollica

Izzo

2015

J. Polym. Sci. Part B: Polym. Phys.

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“…The variation of polymer ionization was achieved by varying its acidity constant, while the solution pH was a result of the simulation. The constant-pH method has been introduced to enable simulations of acid-base ionization reactions at a given pH 43 It has also been used to simulate various polyelectrolyte systems [44][45][46][47][48][49][50][51][52][53] . However, the simulated systems were not explicitly coupled to a reservoir.…”

Section: Introductionmentioning

confidence: 99%

Grand-Reaction Method for Simulations of Ionization Equilibria and Ion Partitioning in a Broad Range of pH and Ionic Strength

Landsgesell¹,

Rud²,

Hebbeker³

et al. 2019

Preprint

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We introduce the grand-reaction method for coarse-grained simulations of acid-base equilibria in a system coupled to a reservoir at a given pH and concentration of added salt. It can be viewed as an extension of the constant-pH method and the reaction ensemble, combining explicit simulations of reactions within the system, and grandcanonical exchange of particles with the reservoir. Unlike the previously introduced methods, the grand-reaction method is applicable to acid-base equilibria in the whole pH range because it avoids known artifacts. However, the method is more general, and can be used for simulations of any reactive system coupled to a reservoir of a known composition. To demonstrate the advantages of the grand-reaction method, we simulated a model system: A solution of weak polyelectrolytes in equilibrium with a buffer solution. By carefully accounting for the exchange of all constituents, the method ensures that all chemical potentials are equal in the system and in the multicomponent reservoir. Thus, the grand-reaction method is able to predict non-monotonic swelling of weak polyelectrolytes as a function of pH, that has been known from meanfield predictions and from experiments but has never been observed in coarse-grained simulations. Finally, we outline possible extensions and further generalizations of the method, and provide a set of guidelines to enable safe usage of the method by a broad community of users.

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“…[5,15,[21][22][23][24][25]. For systems with a small number of sites (N ≤ 20), the necessary thermal averages can be performed by direct enumeration, while for a large number of sites Monte Carlo (MC) simulations become necessary [26][27][28][29][30][31][32][33][34][35][36][37].…”

Section: Introductionmentioning

confidence: 99%

Coupling of Charge Regulation and Conformational Equilibria in Linear Weak Polyelectrolytes: Treatment of Long Range Interactions via Effective Short-Ranged and pH-Dependent Interaction Parameters

Blanco¹,

Madurga²,

Mas³

et al. 2018

Preprint

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The classical Rotational Isomeric State (RIS) model, originally proposed by Flory, has been used to rationalize a wide range of physicochemical properties of neutral polymers. However, many weak polyelectrolytes of interest are able to regulate their charge depending on the conformational state of the bonds. Recently, it has been shown that the RIS model can be coupled with the Site Binding (SB) model, for which the ionizable sites can adopt two states: protonated or deprotonated. The resulting combined scheme, the SBRIS model, allows to analyse ionization and conformational equilibria on the same foot. In the present work this approach is extended to include pH-dependent electrostatic Long Range (LR) interactions, ubiquitous in weak polyelectrolytes at moderate and low ionic strengths. With this aim the original LR interactions are taken into account by defining effective Short Range (SR) and pH-dependent parameters, such as effective microscopic protonation constants and rotational bond energies. The new parameters are systematically calculated using variational methods. The machinery of statistical mechanics for SR interactions, including the powerful and fast transfer matrix methods, can then be applied. The resulting technique, to which we will refer as Local Effective Interaction Parameters (LEIP) method, is illustrated with a minimal model of a flexible linear polyelectrolyte containing only one type of rotating bonds. LEIP reproduces very well the pH dependence of the degree of protonation and bond probabilities obtained by semi-grand canonical Monte Carlo simulations, where LR interactions are taken explicitly into account. The reduction in the computational time in several orders of magnitude suggests that the LEIP technique could be useful in a range of areas involving linear weak polyelectrolytes, allowing direct fitting of the relevant physical parameters to the experimental quantities.

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Influence of Explicit Ions on Titration Curves and Conformations of Flexible Polyelectrolytes: A Monte Carlo Study

Cited by 34 publications

References 58 publications

Influence of charged intramolecular hydrogen bonds in weak polyelectrolytes: A Monte Carlo study of flexible and extendible polymeric chains in solution and near charged spheres

Influence of charged intramolecular hydrogen bonds in weak polyelectrolytes: A Monte Carlo study of flexible and extendible polymeric chains in solution and near charged spheres

Grand-Reaction Method for Simulations of Ionization Equilibria and Ion Partitioning in a Broad Range of pH and Ionic Strength

Coupling of Charge Regulation and Conformational Equilibria in Linear Weak Polyelectrolytes: Treatment of Long Range Interactions via Effective Short-Ranged and pH-Dependent Interaction Parameters

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