Publications

I. Martini, G. Rozza, and Bernard Haasdonk. Reduced basis approximation and a-posteriori error estimation for the coupled Stokes-Darcy system. Advances in Computational Mathematics, (41)5:1131--1157, 2015. [PUMA: Error decomposition; medium 76D07 from:britsteiner Porous Reduced ians method; basis problem; Stokes 76S05; estimation; equation; Domain Non-coercive flow; anm 65N55;] URL

I. Martini, G. Rozza, and Bernard Haasdonk. Reduced basis approximation and a-posteriori error estimation for the coupled Stokes-Darcy system. Advances in Computational Mathematics, (41)5:1131--1157, 2015. [PUMA: 65N55; 76D07 76S05; Domain Error Non-coercive Porous Reduced Stokes anm basis decomposition; equation; estimation; flow; ians medium method; problem;] URL

K.-M. Lin, S. Boschert, P. Dold, K. W. Benz, O. Kriessl, A. Schmidt, K. G. Siebert, and G. Dziuk. Numerical Methods for Industrial Bridgman Growth of (Cd,Zn)Te. Journal of Crystal Growth, (237-239):1736-1740, 2002. [PUMA: Bridgman Fluid Heat Semiconducting cadmium compounds flows; from:mhartmann ians method; transfer; vorlaeufig] URL

I. Martini, G. Rozza, and B. Haasdonk. Reduced basis approximation and a-posteriori error estimation for the coupled Stokes-Darcy system. Advances in Computational Mathematics, (41)5:1131--1157, 2015. [PUMA: 65N55; 76D07 76S05; Domain Error Non-coercive Porous Reduced Stokes basis decomposition; equation; estimation; flow; from:mhartmann ians medium method; problem; vorlaeufig] URL

Stefan Fechter, Claus-Dieter Munz, Christian Rohde, and Christoph Zeiler. A sharp interface method for compressible liquid-vapor flow with phase transition and surface tension. J. Comput. Phys., (336):347-374, 2017. [PUMA: compressible flow; ghost-fluid heat interface latent method; phase resolution; sharp surface tension; transition; two-phase vorlaeufig] URL

K.-M. Lin, S. Boschert, P. Dold, K. W. Benz, O. Kriessl, A. Schmidt, K. G. Siebert, and G. Dziuk. Numerical Methods for Industrial Bridgman Growth of (Cd,Zn)Te. Journal of Crystal Growth, (237-239):1736-1740, 2002. [PUMA: Bridgman Fluid Heat Semiconducting cadmium compounds flows; method; transfer; vorlaeufig] URL

I. Martini, G. Rozza, and B. Haasdonk. Reduced basis approximation and a-posteriori error estimation for the coupled Stokes-Darcy system. Advances in Computational Mathematics, (41)5:1131--1157, 2015. [PUMA: 65N55; 76D07 76S05; Domain Error Non-coercive Porous Reduced Stokes basis decomposition; equation; estimation; flow; medium method; problem; vorlaeufig] URL

Ilja Kr�ker, Wolfgang Nowak, and Christian Rohde. A stochastically and spatially adaptive parallel scheme for uncertain and nonlinear two-phase flow problems. Comput. Geosci., (19)2:269--284, Springer International Publishing, 2015. [PUMA: Finite Galerkin; Hybrid Nonlinear Stochastic method; stochastic volume vorlaeufig] URL

Tushar Bhandari, Fursan Hamad, Christian Moormann, K. G. Sharma, and Bernhard Westrich. Numerical modelling of seismic slope failure using MPM. COMPUTERS AND GEOTECHNICS, (75):126-134, ELSEVIER SCI LTD, THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, OXON, ENGLAND, May 2016. [PUMA: Landslides; Large Method; Non-zero Point Slope condition; deformation; failure} kinematic {Material]

Andrea D. Beck, David G. Flad, Claudia Tonhaeuser, Gregor Gassner, and Claus-Dieter Munz. On the Influence of Polynomial De-aliasing on Subgrid Scale Models. FLOW TURBULENCE AND COMBUSTION, (97)2:475-511, SPRINGER, VAN GODEWIJCKSTRAAT 30, 3311 GZ DORDRECHT, NETHERLANDS, September 2016. [PUMA: Collocation} De-aliasing; Galerkin; Large Smagorinsky Stability; Variational eddy method; model; multiscale simulation; {Discontinuous]

Andrea Barth, and Franz G. Fuchs. UNCERTAINTY QUANTIFICATION FOR HYPERBOLIC CONSERVATION LAWS WITH FLUX COEFFICIENTS GIVEN BY SPATIOTEMPORAL RANDOM FIELDS. SIAM JOURNAL ON SCIENTIFIC COMPUTING, (38)4:A2209-A2231, SIAM PUBLICATIONS, 3600 UNIV CITY SCIENCE CENTER, PHILADELPHIA, PA 19104-2688 USA, 2016. [PUMA: Carlo Gaussian Monte Ornstein-Uhlenbeck differential equation; field; field} finite flux function; hyperbolic method; partial process; quantification; random spatiotemporal uncertainty volume {stochastic]