Your search keyword '"Tomaz Urbic"' showing total 4 results

1. Analytical 2-Dimensional Model of Nonpolar and Ionic Solvation in Water

Author

Ajeet Kumar Yadav, Tomaz Urbic, Ken A. Dill, and Pradipta Bandyopadhyay

Subjects

Quantitative Biology::Biomolecules, Ionic radius, Materials science, 010304 chemical physics, Enthalpy, Solvation, Ionic bonding, Radius, 010402 general chemistry, 01 natural sciences, Article, 0104 chemical sciences, Surfaces, Coatings and Films, Entropy (classical thermodynamics), Dipole, Engineering, Chemical physics, Physical Sciences, Chemical Sciences, 0103 physical sciences, Materials Chemistry, Molecule, Physics::Chemical Physics, Physical and Theoretical Chemistry

Abstract

A goal in computational chemistry is computing hydration free energies of nonpolar and charged solutes accurately, but with much greater computational speeds than in today's explicit-water simulations. Here, we take one step in that direction: a simple model of solvating waters that is analytical and thus essentially instantaneous to compute. Each water molecule is a 2-dimensional dipolar hydrogen-bonding disk that interacts around small circular solutes with different nonpolar and charge interactions. The model gives good qualitative agreement with experiments. As a function of the solute radius, it gives the solvation free energy, enthalpy and entropy as a function of temperature for the inert gas series Ne, Ar, Kr, and Xe. For anions and cations, it captures relatively well the trends versus ion radius. This approach should be readily generalizable to three dimensions.

Published

2021

2. Water Is a Cagey Liquid

Author

Ken A. Dill and Tomaz Urbic

Subjects

Phase transition, Liquid water, Static Electricity, Chemical, 010402 general chemistry, 01 natural sciences, Biochemistry, Phase Transition, Article, Catalysis, Colloid and Surface Chemistry, Models, 0103 physical sciences, Static electricity, Pressure, Molecule, Supercooling, Physics::Atmospheric and Oceanic Physics, 010304 chemical physics, Chemistry, Hydrogen bond, Temperature, Water, Hydrogen Bonding, General Chemistry, 0104 chemical sciences, Temperature and pressure, Models, Chemical, Chemical physics, Chemical Sciences, Thermodynamics, Current (fluid)

Abstract

Liquid water is considered poorly understood. How are water's physical properties encoded in its molecular structure? We introduce a statistical mechanical model (CageWater) of water's hydrogen-bonding (HB) and Lennard-Jones (LJ) interactions. It predicts the energetic and volumetric and anomalous properties accurately. Yet, because the model is analytical, it is essentially instantaneous to compute. This model advances our understanding beyond current molecular simulations and experiments. Water has long been regarded as a "2-density liquid": a dense LJ liquid and a looser HB one. Instead, we find here a different antagonism underlying water structure-property relations: HBs in water-water pairs drive density, while HBs in cooperative cages drive openness. The balance shifts strongly with temperature and pressure. This model interprets the molecular structures underlying the liquid-liquid phase transition in supercooled water. It may have value in geophysics, biomolecular modeling, and engineering of materials for water purification and green chemistry.

Published

2018

3. Simple Model of Hydrophobic Hydration

Author

Miha Lukšič, Barbara Hribar-Lee, Tomaz Urbic, and Ken A. Dill

Subjects

Enthalpy, Monte Carlo method, Thermodynamics, Heat capacity, Article, symbols.namesake, Entropy (classical thermodynamics), Computational chemistry, Pressure, Materials Chemistry, Water model, Physical and Theoretical Chemistry, Aqueous solution, Chemistry, Temperature, Solvation, Water, Hydrogen Bonding, Surfaces, Coatings and Films, Models, Chemical, Solvents, symbols, van der Waals force, Hydrophobic and Hydrophilic Interactions, Monte Carlo Method

Abstract

Water is an unusual liquid in its solvation properties. Here, we model the process of transferring a nonpolar solute into water. Our goal was to capture the physical balance between water's hydrogen bonding and van der Waals interactions in a model that is simple enough to be nearly analytical and not heavily computational. We develop a 2-dimensional Mercedes-Benz-like model of water with which we compute the free energy, enthalpy, entropy, and the heat capacity of transfer as a function of temperature, pressure, and solute size. As validation, we find that this model gives the same trends as Monte Carlo simulations of the underlying 2D model and gives qualitative agreement with experiments. The advantages of this model are that it gives simple insights and that computational time is negligible. It may provide a useful starting point for developing more efficient and more realistic 3D models of aqueous solvation.

Published

2012

4. Confined Water: A Mercedes-Benz Model Study

Author

Vojko Vlachy, Tomaz Urbic, and Ken A. Dill

Subjects

Fourier Analysis, Hydrogen bond, Chemistry, Monte Carlo method, Isotropy, Temperature, Water, Hydrogen Bonding, Molecular physics, Heat capacity, Surfaces, Coatings and Films, Nanopore, Models, Chemical, Computational chemistry, Proton transport, Vaporization, Materials Chemistry, Thermodynamics, Molecule, Computer Simulation, Physical and Theoretical Chemistry, Monte Carlo Method, Physics::Atmospheric and Oceanic Physics

Abstract

We study water that is confined within small geometric spaces. We use the Mercedes-Benz (MB) model of water, in NVT and muVT Monte Carlo computer simulations. For MB water molecules between two planes separated by a distance d, we explore the structures, hydrogen bond networks, and thermodynamics as a function of d, temperature T, and water chemical potential mu. We find that squeezing the planes close enough together leads to a vaporization of waters out of the cavity. This vaporization transition has a corresponding peak in the heat capacity of the water. We also find that, in small pores, hydrogen bonding is not isotropic but, rather, it preferentially forms chains along the axis of the cavity. This may be relevant for fast proton transport in pores. Our simulations show oscillations in the forces between the inert plates, due to water structure, even for plate separations of 5-10 water diameters, consistent with experiments by Israelachvili et al. [Nature 1983, 306, 249]. Finally, we find that confinement affects water's heat capacity, consistent with recent experiments of Tombari et al. on Vycor nanopores [J. Chem. Phys. 2005, 122, 104712].

Published

2006