Your search keyword '"Bonthuis, Douwe Jan"' showing total 23 results

1. Multiscale Modeling of Aqueous Electric Double Layers.

Author

Becker, Maximilian, Loche, Philip, Rezaei, Majid, Wolde-Kidan, Amanuel, Uematsu, Yuki, Netz, Roland R., and Bonthuis, Douwe Jan

Published

2024

2. Nature of Cations Critically Affects Water at the Negatively Charged Silica Interface.

Author

Hunger, Johannes, Schaefer, Jan, Ober, Patrick, Seki, Takakazu, Wang, Yongkang, Prädel, Leon, Nagata, Yuki, Bonn, Mischa, Bonthuis, Douwe Jan, and Backus, Ellen H. G.

Published

2022

3. Exploring the Absorption Spectrum of Simulated Water from MHz to Infrared.

Author

Carlson, Shane, Brünig, Florian N., Loche, Philip, Bonthuis, Douwe Jan, and Netz, Roland R.

Published

2020

4. Unraveling the Origin of the Apparent Charge of Zwitterionic Lipid Layers.

Author

Dreier, Lisa B., Wolde-Kidan, Amanuel, Bonthuis, Douwe Jan, Netz, Roland R., Backus, Ellen H.G., and Bonn, Mischa

Published

2019

5. Crossover of the Power-Law Exponent for Carbon Nanotube Conductivity as a Function of Salinity.

Author

Yuki Uematsu, Netz, Roland R., Bocquet, Lydéric, and Bonthuis, Douwe Jan

Published

2018

6. Unraveling the CombinedEffects of Dielectric andViscosity Profiles on Surface Capacitance, Electro-Osmotic Mobility,and Electric Surface Conductivity.

Author

Bonthuis, Douwe Jan and Netz, Roland R.

Subjects

*DIELECTRICS, *VISCOSITY, *SURFACES (Technology), *ELECTRO-osmosis, *HYDROPHOBIC surfaces, *SOLID-liquid interfaces, *ELECTROSTATICS

Abstract

We calculate the electro-osmotic mobility and surfaceconductivityat a solid–liquid interface from a modified Poisson–Boltzmannequation, including spatial variations of the dielectric functionand the viscosity that where extracted previously from molecular dynamicssimulations of aqueous interfaces. The low-dielectric region directlyat the interface leads to a substantially reduced surface capacitance.At the same time, ions accumulate into a highly condensed interfaciallayer, leading to the well-known saturation of the electro-osmoticmobility at large surface charge density regardless of the hydrodynamicboundary conditions. The experimentally well-established apparentexcess surface conductivity follows from our model for all hydrodynamicboundary conditions without additional assumptions. Our theory fitsmultiple published sets of experimental data on hydrophilic and hydrophobicsurfaces with striking accuracy, using the nonelectrostatic ion–surfaceinteraction as the only fitting parameter. [ABSTRACT FROM AUTHOR]

Published

2012

7. Profile of the StaticPermittivity Tensor of Waterat Interfaces: Consequences for Capacitance, Hydration Interactionand Ion Adsorption.

Author

Bonthuis, Douwe Jan, Gekle, Stephan, and Netz, Roland R.

Subjects

*CAPACITANCE meters, *HYDRATION, *ADSORPTION (Chemistry), *PERMITTIVITY, *TENSOR algebra, *DIELECTRICS, *ELECTROSTATICS

Abstract

We derive the theoretical framework to calculate thedielectricresponse tensor and determine its components for water adjacent tohydrophilic and hydrophobic surfaces using molecular dynamics simulations.For the nonpolarizable water model used, linear response theory isfound to be applicable up to an external perpendicular field strengthof ∼2 V/nm, which is well beyond the experimental dielectricbreakdown threshold. The dipole contribution dominates the dielectricresponse parallel to the interface, whereas for the perpendicularcomponent it is essential to keep the quadrupole and octupole terms.Including the space-dependent dielectric function in a mean-fielddescription of the ion distribution at a single charged interface,we reproduce experimental values of the interfacial capacitance. Atthe same time, the dielectric function decreases the electrostaticpart of the disjoining pressure between two charged surfaces, unlikepreviously thought. The difference in interfacial polarizability betweenhydrophilic and hydrophobic surfaces can be quantized in terms ofthe dielectric dividing surface. Using the dielectric dividing surfaceand the Gibbs dividing surface positions to estimate the free energyof a single ion close to an interface, ion-specific adsorption effectsare found to be more pronounced at hydrophobic surfaces than at hydrophilicsurfaces, in agreement with experimental trends. [ABSTRACT FROM AUTHOR]

Published

2012

8. Nanoscale Pumping of Water by AC Electric Fields.

Author

Rinne, Klaus F., Gekle, Stephan, Bonthuis, Douwe Jan, and Netz, Roland R.

Published

2012

9. Short-Range Cooperative Slow-down of Water Solvation Dynamics Around SO 4 2- -Mg 2+ Ion Pairs.

Author

Kundu A, Mamatkulov SI, Brünig FN, Bonthuis DJ, Netz RR, Elsaesser T, and Fingerhut BP

Abstract

The presence of ions affects the structure and dynamics of water on a multitude of length and time scales. In this context, pairs of Mg 2+ and SO 4 2- ions in water constitute a prototypical system for which conflicting pictures of hydration geometries and dynamics have been reported. Key issues are the molecular pair and solvation shell geometries, the spatial range of electric interactions, and their impact on solvation dynamics. Here, we introduce asymmetric SO 4 2- stretching vibrations as new and most specific local probes of solvation dynamics that allow to access ion hydration dynamics at the dilute concentration (0.2 M) of a native electrolyte environment. Highly sensitive heterodyne 2D-IR spectroscopy in the fingerprint region of the SO 4 2- ions around 1100 cm -1 reveals a specific slow-down of solvation dynamics for hydrated MgSO 4 and for Na 2 SO 4 in the presence of Mg 2+ ions, which manifests as a retardation of spectral diffusion compared to aqueous Na 2 SO 4 solutions in the absence of Mg 2+ ions. Extensive molecular dynamics and density functional theory QM/MM simulations provide a microscopic view of the observed ultrafast dephasing and hydration dynamics. They suggest a molecular picture where the slow-down of hydration dynamics arises from the structural peculiarities of solvent-shared SO 4 2- -Mg 2+ ion pairs., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

10. Transferable Ion Force Fields in Water from a Simultaneous Optimization of Ion Solvation and Ion-Ion Interaction.

Author

Loche P, Steinbrunner P, Friedowitz S, Netz RR, and Bonthuis DJ

Subjects

Entropy, Ions, Thermodynamics, Water

Abstract

The poor performance of many existing nonpolarizable ion force fields is typically blamed on either the lack of explicit polarizability, the absence of charge transfer, or the use of unreduced Coulomb interactions. However, this analysis disregards the large and mostly unexplored parameter range offered by the Lennard-Jones potential. We use a global optimization procedure to develop water-model-transferable force fields for the ions K + , Na + , Cl - , and Br - in the complete parameter space of all Lennard-Jones interactions using standard mixing rules. No extra-thermodynamic assumption is necessary for the simultaneous optimization of the four ion pairs. After an optimization with respect to the experimental solvation free energy and activity, the force fields reproduce the concentration-dependent density, ionic conductivity, and dielectric constant with high accuracy. The force field is fully transferable between simple point charge/extended and transferable intermolecular potential water models. Our results show that a thermodynamically consistent force field for these ions needs only Lennard-Jones and standard Coulomb interactions.

Published

2021

11. Interfacial, Electroviscous, and Nonlinear Dielectric Effects on Electrokinetics at Highly Charged Surfaces.

Author

Rezaei M, Mitterwallner BG, Loche P, Uematsu Y, Netz RR, and Bonthuis DJ

Abstract

The dielectric constant and the viscosity of water at the interface of hydrophilic surfaces differ from their bulk values, and it has been proposed that the deviation is caused by the strong electric field and the high ion concentration in the interfacial layer. We calculate the dependence of the dielectric constant and the viscosity of bulk electrolytes on the electric field and the salt concentration. Incorporating the concentration and field-dependent dielectric constant and viscosity in the extended Poisson-Boltzmann and Stokes equations, we calculate the electro-osmotic mobility. We compare the results to literature experimental data and explicit molecular dynamics simulations of OH-terminated surfaces and show that it is necessary to additionally include the presence of a subnanometer wide interfacial water layer, the properties of which are drastically transformed by the sheer presence of the interface. We conclude that the origin of the anomalous behavior of aqueous interfacial layers cannot be found in electrostriction or electroviscous effects caused by the interfacial electric field and ion concentration. Instead, it is primarily caused by the intrinsic ordering and orientation of the interfacial water layer.

Published

2021

12. Ionic Surfactants at Air/Water and Oil/Water Interfaces: A Comparison Based on Molecular Dynamics Simulations.

Author

Müller P, Bonthuis DJ, Miller R, and Schneck E

Abstract

Ionic surfactants are known to build up higher interfacial pressures at oil/water interfaces than at air/water interfaces for the same surfactant bulk concentration. Here, we systematically investigate this effect through atomistic molecular dynamics (MD) simulations of surfactant-loaded air/water and oil/water interfaces. Two prototypical ionic surfactants, C 12 TAB and sodium dodecyl sulfate (SDS), are studied and found to give consistent results, which are also robust with respect to variations in the simulation force field. The simulations reproduce the experimental interfacial pressure data on a semiquantitative level and reveal that the influence of oil on the surfactants' in-plane distribution is a major contribution to the observed effect, albeit insufficient to be the sole reason. The simulations are further analyzed with regard to surfactant/oil cooperative/competitive effects that have been invoked recently as an explanation. However, the interfacial orientation of oil molecules, a presumable indicator for such behavior, is found to display changes only for high levels of surfactant coverage.

Published

2021

13. Nanomolar Surface-Active Charged Impurities Account for the Zeta Potential of Hydrophobic Surfaces.

Author

Uematsu Y, Bonthuis DJ, and Netz RR

Abstract

The electrification of hydrophobic surfaces is an intensely debated subject in physical chemistry. We theoretically study the ζ potential of hydrophobic surfaces for varying pH and salt concentration by solving the Poisson-Boltzmann and Stokes equations with individual ionic adsorption affinities. Using the ionic surface affinities extracted from the experimentally measured surface tension of the air-electrolyte interface, we first show that the interfacial adsorption and repulsion of small inorganic ions such as H 3 O + , OH - , HCO 3 - , and CO 3 2- cannot account for the ζ potential observed in experiments because the surface affinities of these ions are too small. Even if we take hydrodynamic slip into account, the characteristic dependence of the ζ potential on pH and salt concentration cannot be reproduced. Instead, to explain the sizable experimentally measured ζ potential of hydrophobic surfaces, we assume minute amounts of impurities in the water and include the impurities' acidic and basic reactions with water. We find good agreement between our predictions and the reported experimental ζ potential data of various hydrophobic surfaces if we account for impurities that consist of a mixture of weak acids (p K a = 5-7) and weak bases (p K b = 12) at a concentration of the order of 10 -7 M.

Published

2020

14. Breakdown of Linear Dielectric Theory for the Interaction between Hydrated Ions and Graphene.

Author

Loche P, Ayaz C, Schlaich A, Bonthuis DJ, and Netz RR

Abstract

Many vital processes taking place in electrolytes, such as nanoparticle self-assembly, water purification, and the operation of aqueous supercapacitors, rely on the precise many-body interactions between surfaces and ions in water. Here we study the interaction between a hydrated ion and a charge-neutral graphene layer using atomistic molecular dynamics simulations. For small separations, the ion-graphene repulsion is of nonelectrostatic nature, and for intermediate separations, van der Waals attraction becomes important. Contrary to prevailing theory, we show that nonlinear and tensorial dielectric effects become non-negligible close to surfaces, even for monovalent ions. This breakdown of standard isotropic linear dielectric theory has important consequences for the understanding and modeling of charged objects at surfaces.

Published

2018

15. Analytical Interfacial Layer Model for the Capacitance and Electrokinetics of Charged Aqueous Interfaces.

Author

Uematsu Y, Netz RR, and Bonthuis DJ

Abstract

We construct an analytical model to account for the influence of the subnanometer-wide interfacial layer on the differential capacitance and the electro-osmotic mobility of solid-electrolyte interfaces. The interfacial layer is incorporated into the Poisson-Boltzmann and Stokes equations using a box model for the dielectric properties, the viscosity, and the ionic potential of mean force. We calculate the differential capacitance and the electro-osmotic mobility as a function of the surface charge density and the salt concentration, both with and without steric interactions between the ions. We compare the results from our theoretical model with experimental data on a variety of systems (graphite and metallic silver for capacitance and titanium oxide and silver iodide for electro-osmotic data). The differential capacitance of silver as a function of salinity and surface charge density is well reproduced by our theory, using either the width of the interfacial layer or the ionic potential of mean force as the only fitting parameter. The differential capacitance of graphite, however, needs an additional carbon capacitance to explain the experimental data. Our theory yields a power-law dependence of the electro-osmotic mobility on the surface charge density for high surface charges, reproducing the experimental data using both the interfacial parameters extracted from molecular dynamics simulations and fitted interfacial parameters. Finally, we examine different types of hydrodynamic boundary conditions for the power-law behavior of the electro-osmotic mobility, showing that a finite-viscosity layer explains the experimental data better than the usual hydrodynamic slip boundary condition. Our analytical model thus allows us to extract the properties of the subnanometer-wide interfacial layer by fitting to macroscopic experimental data.

Published

2018

16. Crossover of the Power-Law Exponent for Carbon Nanotube Conductivity as a Function of Salinity.

Author

Uematsu Y, Netz RR, Bocquet L, and Bonthuis DJ

Abstract

On the basis of the Poisson-Boltzmann equation in cylindrical coordinates, we calculate the conductivity of a single charged nanotube filled with electrolyte. The conductivity as a function of the salt concentration follows a power-law, the exponent of which has been controversially discussed in the literature. We use the co-ion-exclusion approximation and obtain the crossover between different asymptotic power-law behaviors analytically. Numerically solving the full Poisson-Boltzmann equation, we also calculate the complete diagram of exponents as a function of the salt concentration and the pH for tubes with different radii and p K a values. We apply our theory to recent experimental results on carbon nanotubes using the p K a as a fit parameter. In good agreement with the experimental data, the theory shows power-law behavior with the exponents 1/3 at high pH and 1/2 at low pH, with a crossover depending on salt concentration, tube radius and p K a .

Published

2018

17. Charged Surface-Active Impurities at Nanomolar Concentration Induce Jones-Ray Effect.

Author

Uematsu Y, Bonthuis DJ, and Netz RR

Abstract

The electrolyte surface tension exhibits a characteristic minimum around a salt concentration of 1 mM for all ion types, known as the Jones-Ray effect. We show that a consistent description of the experimental surface tension of salts, bases, and acids is possible by assuming charged impurities in the water with a surface affinity typical for surfactants. Comparison with experimental data yields an impurity concentration in the nanomolar range, well below the typical experimental detection limit. Our modeling reveals salt-screening enhanced impurity adsorption as the mechanism behind the Jones-Ray effect: for very low salt concentration added salt screens the  electrostatic repulsion between impurities at the surface, which dramatically increases impurity adsorption and thereby reduces the surface tension.

Published

2018

18. The Power Spectrum of Ionic Nanopore Currents: The Role of Ion Correlations.

Author

Zorkot M, Golestanian R, and Bonthuis DJ

Abstract

We calculate the power spectrum of electric-field-driven ion transport through nanometer-scale membrane pores using both linearized mean-field theory and Langevin dynamics simulations. Remarkably, the linearized mean-field theory predicts a plateau in the power spectral density at low frequency ω, which is confirmed by the simulations at low ion concentration. At high ion concentration, however, the power spectral density follows a power law that is reminiscent of the 1/ω(α) dependence found experimentally at low frequency. On the basis of simulations with and without ion-ion interactions, we attribute the low-frequency power-law dependence to ion-ion correlations. We show that neither a static surface charge density, nor an increased pore length, nor an increased ion valency have a significant effect on the shape of the power spectral density at low frequency.

Published

2016

19. Beyond the continuum: how molecular solvent structure affects electrostatics and hydrodynamics at solid-electrolyte interfaces.

Author

Bonthuis DJ and Netz RR

Subjects

Algorithms, Chlorides chemistry, Diamond chemistry, Electric Capacitance, Hydrophobic and Hydrophilic Interactions, Ions chemistry, Linear Models, Models, Molecular, Nonlinear Dynamics, Salts chemistry, Sodium chemistry, Solutions, Viscosity, Electrolytes chemistry, Hydrodynamics, Molecular Dynamics Simulation, Solvents chemistry, Static Electricity, Water chemistry

Abstract

Standard continuum theory fails to predict several key experimental results of electrostatic and electrokinetic measurements at aqueous electrolyte interfaces. In order to extend the continuum theory to include the effects of molecular solvent structure, we generalize the equations for electrokinetic transport to incorporate a space dependent dielectric profile, viscosity profile, and non-electrostatic interaction potential. All necessary profiles are extracted from atomistic molecular dynamics (MD) simulations. We show that the MD results for the ion-specific distribution of counterions at charged hydrophilic and hydrophobic interfaces are accurately reproduced using the dielectric profile of pure water and a non-electrostatic repulsion in an extended Poisson-Boltzmann equation. The distributions of Na(+) at both surface types and Cl(-) at hydrophilic surfaces can be modeled using linear dielectric response theory, whereas for Cl(-) at hydrophobic surfaces it is necessary to apply nonlinear response theory. The extended Poisson-Boltzmann equation reproduces the experimental values of the double-layer capacitance for many different carbon-based surfaces. In conjunction with a generalized hydrodynamic theory that accounts for a space dependent viscosity, the model captures the experimentally observed saturation of the electrokinetic mobility as a function of the bare surface charge density and the so-called anomalous double-layer conductivity. The two-scale approach employed here-MD simulations and continuum theory-constitutes a successful modeling scheme, providing basic insight into the molecular origins of the static and kinetic properties of charged surfaces, and allowing quantitative modeling at low computational cost.

Published

2013

20. Electrokinetics at aqueous interfaces without mobile charges.

Author

Bonthuis DJ, Horinek D, Bocquet L, and Netz RR

Abstract

We theoretically consider the possibility of using electric fields in aqueous channels of cylindrical and planar geometry to induce transport in the absence of mobile ionic charges. Using the Navier-Stokes equation, generalized to include the effects of water spinning, dipole orientation and relaxation, we show analytically that pumping of a dipolar liquid through an uncharged hydrophobic channel can be achieved by injecting torque into the liquid, based on the coupling between molecular spinning and fluid vorticity. This is possible using rotating electric fields and suitably chosen interfacial boundary conditions or transiently by suddenly switching on a homogeneous electric field. A static electric field, however, does not induce a steady state flow in channels, irrespective of the geometry. Using molecular dynamics (MD) simulations, we confirm that static fields do not lead to any pumping, in contrast to earlier publications. The pumping observed in MD simulations of carbon nanotubes and oil droplets in a static electric field is tracked down to an imprudent implementation of Lennard-Jones interaction truncation schemes.

Published

2010

21. Molecular hydrophobic attraction and ion-specific effects studied by molecular dynamics.

Author

Horinek D, Serr A, Bonthuis DJ, Boström M, Kunz W, and Netz RR

Subjects

Adsorption, Amino Acids chemistry, Hydrophobic and Hydrophilic Interactions, Ions chemistry, Microscopy, Atomic Force methods, Peptides chemistry, Proteins chemistry, Sodium Chloride chemistry, Static Electricity, Surface Properties, Water chemistry, Computer Simulation, Models, Chemical

Abstract

Much is written about "hydrophobic forces" that act between solvated molecules and nonpolar interfaces, but it is not always clear what causes these forces and whether they should be labeled as hydrophobic. Hydrophobic effects roughly fall in two classes, those that are influenced by the addition of salt and those that are not. Bubble adsorption and cavitation effects plague experiments and simulations of interacting extended hydrophobic surfaces and lead to a strong, almost irreversible attraction that has little or no dependence on salt type and concentration. In this paper, we are concerned with hydrophobic interactions between single molecules and extended surfaces and try to elucidate the relation to electrostatic and ion-specific effects. For these nanoscopic hydrophobic forces, bubbles and cavitation effects play only a minor role and even if present cause no equilibration problems. In specific, we study the forced desorption of peptides from nonpolar interfaces by means of molecular dynamics simulations and determine the adsorption potential of mean force. The simulation results for peptides compare well with corresponding AFM experiments. An analysis of the various contributions to the total peptide-surface interactions shows that structural effects of water as well as van der Waals interactions between surface and peptide are important. Hofmeister ion effects are studied by separately determining the effective interaction of various ions with hydrophobic surfaces. An extension of the Poisson-Boltzmann equation that includes the ion-specific potential of mean force yields surface potentials, interfacial tensions, and effective interactions between hydrophobic surfaces. There, we also analyze the energetic contributions to the potential of mean force and find that the most important factor determining ion-specific adsorption at hydrophobic surfaces can best be described as surface-modified ion hydration.

Published

2008

22. Power generation by pressure-driven transport of ions in nanofluidic channels.

Author

van der Heyden FH, Bonthuis DJ, Stein D, Meyer C, and Dekker C

Subjects

Electrochemistry methods, Equipment Design, Equipment Failure Analysis, Ions, Microfluidics methods, Nanotechnology methods, Pressure, Electric Power Supplies, Electricity, Electrochemistry instrumentation, Microfluidics instrumentation, Nanotechnology instrumentation

Abstract

We report on the efficiency of electrical power generation in individual rectangular nanochannels by means of streaming currents, the pressure-driven transport of counterions in the electrical double layer. Our experimental study as a function of channel height and salt concentration reveals that the highest efficiency occurs when double layers overlap, which corresponds to nanoscale fluidic channels filled with aqueous solutions of low ionic strength. The highest efficiency of approximately 3% was found for a 75 nm high channel, the smallest channel measured. The data are well described by Poisson-Boltzmann theory with an additional electrical conductance of the Stern layer.

Published

2007

23. Electrokinetic energy conversion efficiency in nanofluidic channels.

Author

van der Heyden FH, Bonthuis DJ, Stein D, Meyer C, and Dekker C

Subjects

Computer Simulation, Computer-Aided Design, Equipment Design, Equipment Failure Analysis, Kinetics, Microfluidics methods, Nanotechnology methods, Electric Power Supplies, Electricity, Energy Transfer, Microfluidics instrumentation, Models, Theoretical, Nanotechnology instrumentation, Transducers

Abstract

We theoretically evaluate the prospect of using electrokinetic phenomena to convert hydrostatic energy to electrical power. An expression is derived for the energy conversion efficiency of a two-terminal fluidic device in terms of its linear electrokinetic response properties. For a slitlike nanochannel of constant surface charge density, we predict that the maximum energy conversion efficiency occurs at low salt concentrations. An analytic expression for the regime of strong double-layer overlap reveals that the efficiency depends only on the ratio of the channel height to the Gouy-Chapman length, and the product of the viscosity and the counterion mobility. We estimate that an electrokinetic energy conversion device could achieve a maximum efficiency of 12% for simple monovalent ions in aqueous solution.

Published

2006