Jens Smiatek, Marcello Sega, Christian Holm, Ulf D. Schiller, und Friederike Schmid. Mesoscopic simulations of the counterion-induced electro-osmotic flow: A comparative study. Journal of Chemical Physics, (130)244702Juni 2009. [PUMA: Boltzmann dynamics flow lattice mesoscopic method; methods; molecular osmosis; simulation; slip systems;]

Celeste Sagui, und Thomas A. Darden. P3M and PME: A comparison of the two methods. In Lawrence R. Pratt, und Gerhard Hummer (Hrsg.), Simulation and theory of electrostatic interactions in solution, 104--113, AIP, 1999. [PUMA: Brillouin Poisson approximations; constants; crystal electric electrostatics; equation lattice least potential; solutions; squares structure; thermodynamics; zones;]

Ariel Narvaez, Kazem Yazdchi, Stefan Luding, und Jens Harting. From creeping to inertial flow in porous media: a lattice Boltzmann-finite element study. JOURNAL OF STATISTICAL MECHANICS-THEORY AND EXPERIMENT, IOP PUBLISHING LTD, TEMPLE CIRCUS, TEMPLE WAY, BRISTOL BS1 6BE, ENGLAND, Februar 2013. [PUMA: Boltzmann flow fluid in lattice media; methods} models; porous {discrete]

Jonghoon Lee, Burkhard Du\"nweg, und Jo\"rg Schumacher. Multiscale modelling strategy using the lattice Boltzmann method for polymer dynamics in a turbulent flow. Computers & Mathematics with Applications, (59)7:2374--2379, April 2010. [PUMA: Boltzmann; Drag Lattice Polymer Turbulent dynamics; flow; reduction] URL

C. Kunert, und J. Harting. On the effect of surfactant adsorption and viscosity change on apparent slip in hydrophobic microchannels. Progress in Computational Fluid Dynamics, (8):197, 2008. [PUMA: Boltzmann Liquid-solid Wall and apparent interfaces, lattice slip slip,]

Aslin Izmitli, David C. Schwartz, Michael D. Graham, und Juan J. de Pablo. The effect of hydrodynamic interactions on the dynamics of DNA translocation through pores. Journal of Chemical Physics, (128)8:085102, AIP, 2008. [PUMA: Boltzmann DNA; biodiffusion; biophysics hydrodynamics; lattice methods; molecular]

Henning Hörstermann, und Reinhard Hentschke. Volumetric Changes of Randomly Crosslinked Model Networks. Macromolecular Theory and Simulations, (16)4:407--411, WILEY-VCH Verlag, 2007. [PUMA: dynamics, lattice models, molecular networks, polymer shrinkage volume]

Owen A. Hickey, und Christian Holm. Electrophoretic mobility reversal of polyampholytes induced by strong electric fields or confinement. Journal of Chemical Physics, (138)19:194905, AIP, 2013. [PUMA: Boltzmann confined dynamics electrohydrodynamics; electrophoresis; flow flow; lattice method methods; molecular simulation;]

H. J. Herrmann, und M. Müller. Simulations of granular materials on different scales. Computer Physics Communications, (127):120--125, 2000. [PUMA: Computer Computerized Granular Lattice Materials Molecular Particle Stochastic Theoretical collision; dynamics; materials; model; properties; science; simulation; study]

J. Harting, T. Zauner, R. Weeber, und R. Hilfer. Flow in porous media and driven colloidal suspensions. Institute for Computational Physics, University of Stuttgart, Germany, 2008. [PUMA: Boltzmann, Lattice colloidal crystal media, optical permeability, porous tweezer,]

J. Harting, M. Hecht, H. J. Herrmann, und S. McNamara. Computer simulation of particle suspensions. Multifield Problems in Solid and Fluid Mechanis, Lecture Notes in Applied and Computational Mechanics 28, Springer, 2006. [PUMA: Boltzmann Particle dynamics, lattice method molecular rotation stochastic suspensions,]

J. Harting, J. Chin, M. Venturoli, und P. V. Coveney. Large-scale lattice Boltzmann simulations of complex fluids: advances through the advent of computational grids. Philosophical Transactions of the Royal Society of London A, (363):1895--1915, August 2005. [PUMA: Boltzmann, RealityGrid, complex computational computing, fluids grid gyroid lattice media, mesophase, porous steering,]

F. Gunther, F. Janoschek, S. Frijters, und J. Harting. Lattice Boltzmann simulations of anisotropic particles at liquid interfaces. COMPUTERS & FLUIDS, (80)SI:184-189, PERGAMON-ELSEVIER SCIENCE LTD, THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, ENGLAND, Juli 2013. [PUMA: Blue Boltzmann Domain Ellipsoid} Gene/P; Lattice Parallelization; colloidal decomposition; fluid; method; {Complex]

N. González-Segredo, J. Harting, G. Giupponi, und P. V. Coveney. Stress response and structural transitions in sheared gyroidal and lamellar amphiphilic mesophases: lattice-Boltzmann simulations. Physical Review E, (73)3:031503, März 2006. [PUMA: Boltzmann Crystals, Gyroid Lattice Liquid Mesophase, Response, Shear, Stress]

G. Giupponi, J. Harting, und P. V. Coveney. Emergence of rheological properties in lattice Boltzmann simulations of gyroid mesophases. Europhysics Letters, (73):533--539, 2006. [PUMA: Boltzmann, amphiphilic complex fluids, gyroid lattice mesophase, shear systems thinning, viscoelasticity,]

F. Figueirido, G. S. Delbuono, und R. M. Levy. On finite-size effects in computer-simulations using the Ewald Potential. Journal of Chemical Physics, (103)14:6133--6142, 1995. [PUMA: Molecular-dynamics, dielectric-properties, electrostatic enengy, free interactions, lattice particle polypeptides, proteins, solvated sums, systems, water,]

B. Dünweg, und A. J. C. Ladd. Lattice Boltzmann Simulations of Soft Matter Systems. Advanced Computer Simulation Approaches for Soft Matter Sciences III, (221):89--166, Springer-Verlag Berlin, Berlin, Germany, 2009. [PUMA: Boltzmann; Boundary Brownian Chapman-Enskog; Colloidal Fluctuation-dissipation Force Hydrodynamic Lattice Polymer Soft conditions; coupling; dispersions; interactions; matter motion; screening; solutions; theorem;]

Lindsay M. Crowl, und Aaron L. Fogelson. Computational model of whole blood exhibiting lateral platelet motion induced by red blood cells. International Journal for Numerical Methods in Biomedical Engineering, (26)3-4:471--487, John Wiley & Sons, Ltd., 2010. [PUMA: Boltzmann Boundary Immersed blood cell excess, lattice mechanics membrane method, methods, near platelet red wall]

A. Coniglio, und H. J. Herrmann. Phase Transitions in Granular Packings. Physica A, (225):1--6, 1996. [PUMA: Frustrated Gas Heap Lattice Percolation Simulations Slope Tail Theory]

E. Caglioti, A. Coniglio, H. J. Herrmann, V. Loreto, und M. Nicodemi. Segregation of granular mixtures in presence of compaction. Europhysics Letters, (43):591--597, 1998. [PUMA: Ising Nonequilibrium and granular irreversible lattice materials; porous problems; processes statistics; theory thermodynamics;]