Ulrich W. Suter

Bio: Ulrich W. Suter is an academic researcher from ETH Zurich. The author has contributed to research in topics: Polymer & Adsorption. The author has an hindex of 63, co-authored 286 publications receiving 14175 citations. Previous affiliations of Ulrich W. Suter include Massachusetts Institute of Technology & AkzoNobel.

Glossary of basic terms in polymer science (IUPAC Recommendations 1996)

Abstract: Titular Members: G. Allegra (Italy, to 1989); R. E. Bareiss (Germany, to 1993); N. M. Bikales (USA, Secretary to 1987); K. Hatada (Japan, Associate Member from 1987, Titular Member from 1989); A. D. Jenkins (UK, Chairman to 1985, Associate Member to 1987); J. Kahovec (Czech Republic, Associate Member from 1987, Titular Member from 1991); P. Kratochvíl (Czech Republic, Chairman to 1991); E. Maréchal (France, Associate Member from 1991, Titular Member from 1993); W. V. Metanomski (USA, Associate Member from 1987, Titular Member from 1991); I. Mita (Japan, Titular Member to 1989, Associate Member to 1991); C. Noël (France, to 1993); I. M. Papisov (Russia, to 1987, Associate Member to 1991); V. P. Shibaev (Russia, from 1987); R. F. T. Stepto (UK, Associate Member from 1987, Titular Member from 1989, Chairman from 1991); U. W. Suter (Switzerland, to 1991, Associate Member to 1993); W. J. Work (USA, Associate Member from 1985, Secretary from 1987).

Atomistic modeling of mechanical properties of polymeric glasses

Abstract: Methodes pour la prevision des constantes elastiques d'un polymere amorphe par deformation de faible amplitude de structures modeles detaillees microscopiquement

Simulation of polyethylene above and below the melting point

Abstract: Polyethylene at equilibrium is studied by computer simulation. Configuration space is sampled efficiently by a novel Monte Carlo simulation scheme developed for the study of long molecules at high densities. Simulations are carried out in an isobaric‐isothermal statistical‐mechanical ensemble which permits calculation of the density of the polymer matrix at specified conditions of pressure and temperature. A systematic study of the polymer at different temperatures indicates a phase transition; in agreement with experiment, at low temperatures, the polyethylene model studied here crystallizes spontaneously. At temperatures above the melting point, the simulated melt is described accurately by the model.

COMPASS: An ab Initio Force-Field Optimized for Condensed-Phase ApplicationsOverview with Details on Alkane and Benzene Compounds

Abstract: A general all-atom force field for atomistic simulation of common organic molecules, inorganic small molecules, and polymers was developed using state-of-the-art ab initio and empirical parametrization techniques. The valence parameters and atomic partial charges were derived by fitting to ab initio data, and the van der Waals (vdW) parameters were derived by conducting MD simulations of molecular liquids and fitting the simulated cohesive energies and equilibrium densities to experimental data. The combined parametrization procedure significantly improves the quality of a general force field. Validation studies based on large number of isolated molecules, molecular liquids and molecular crystals, representing 28 molecular classes, show that the present force field enables accurate and simultaneous prediction of structural, conformational, vibrational, and thermophysical properties for a broad range of molecules in isolation and in condensed phases. Detailed results of the parametrization and validation f...

Dissipative particle dynamics : bridging the gap between atomistic and mesoscopic simulation

Abstract: We critically review dissipative particle dynamics (DPD) as a mesoscopic simulation method. We have established useful parameter ranges for simulations, and have made a link between these parameters and χ-parameters in Flory-Huggins-type models. This is possible because the equation of state of the DPD fluid is essentially quadratic in density. This link opens the way to do large scale simulations, effectively describing millions of atoms, by firstly performing simulations of molecular fragments retaining all atomistic details to derive χ-parameters, then secondly using these results as input to a DPD simulation to study the formation of micelles, networks, mesophases and so forth. As an example application, we have calculated the interfacial tension σ between homopolymer melts as a function of χ and N and have found a universal scaling collapse when σ/ρkBTχ0.4 is plotted against χN for N>1. We also discuss the use of DPD to simulate the dynamics of mesoscopic systems, and indicate a possible problem with...