| Combustion J Warnatz, U Maas, RW Dibble, J Warnatz Springer-Verlag Berlin Heidelberg, 2006 | 3786 | 2006 |
| Simplifying chemical kinetics: intrinsic low-dimensional manifolds in composition space U Maas, SB Pope Combustion and flame 88 (3-4), 239-264, 1992 | 2138 | 1992 |
| Ignition processes in hydrogen oxygen mixtures U Maas, J Warnatz Combustion and flame 74 (1), 53-69, 1988 | 730 | 1988 |
| Verbrennung J Warnatz, U Maas, RW Dibble Springer, 2006 | 675* | 2006 |
| Implementation of simplified chemical kinetics based on intrinsic low-dimensional manifolds U Maas, SB Pope Symposium (international) on combustion 24 (1), 103-112, 1992 | 433 | 1992 |
| Investigations on pre-ignition in highly supercharged SI engines C Dahnz, KM Han, U Spicher, M Magar, R Schießl, U Maas SAE International Journal of Engines 3 (1), 214-224, 2010 | 312 | 2010 |
| The extension of the ILDM concept to reaction–diffusion manifolds V Bykov, U Maas Combustion Theory and Modelling 11 (6), 839-862, 2007 | 299 | 2007 |
| Laminar flame calculations using simplified chemical kinetics based on intrinsic low-dimensional manifolds U Maas, SB Pope Symposium (International) on Combustion 25 (1), 1349-1356, 1994 | 173 | 1994 |
| Efficient calculation of intrinsic low-dimensional manifolds for the simplification of chemical kinetics U Maas Computing and Visualization in Science 1, 69-81, 1998 | 143 | 1998 |
| Monte Carlo PDF modelling of a turbulent natural-gas diffusion flame PA Nooren, HA Wouters, TWJ Peeters, D Roekaerts, U Maas, D Schmidt Taylor & Francis Group 1 (1), 79-96, 1997 | 139 | 1997 |
| Model reduction for combustion chemistry DA Goussis, U Maas Turbulent combustion modeling: advances, new trends and perspectives, 193-220, 2011 | 133 | 2011 |
| Numerical simulation of spark ignition including ionization M Thiele, S Selle, U Riedel, J Warnatz, U Maas Proceedings of the combustion institute 28 (1), 1177-1185, 2000 | 129 | 2000 |
| Spark ignition of turbulent methane/air mixtures revealed by time-resolved planar laser-induced fluorescence and direct numerical simulations CF Kaminski, J Hult, M Aldén, S Lindenmaier, A Dreizler, U Maas, ... Proceedings of the Combustion Institute 28 (1), 399-405, 2000 | 107 | 2000 |
| Problem adapted reduced models based on Reaction–Diffusion Manifolds (REDIMs) V Bykov, U Maas Proceedings of the Combustion Institute 32 (1), 561-568, 2009 | 106 | 2009 |
| Simplifying chemical kinetics: Trajectory-generated low-dimensional manifolds SB Pope, U Maas Mechanical and Aerospace Engineering Report: FDA 11, 1993 | 105 | 1993 |
| Ignition delay times of diethyl ether measured in a high-pressure shock tube and a rapid compression machine M Werler, LR Cancino, R Schießl, U Maas, C Schulz, M Fikri Proceedings of the Combustion Institute 35 (1), 259-266, 2015 | 102 | 2015 |
| Premature flame initiation in a turbocharged DISI engine-numerical and experimental investigations S Palaveev, M Magar, H Kubach, R Schiessl, U Spicher, U Maas SAE International Journal of Engines 6 (1), 54-66, 2013 | 99 | 2013 |
| Development of a parallel direct simulation code to investigate reactive flows D Thévenin, F Behrendt, U Maas, B Przywara, J Warnatz Computers & fluids 25 (5), 485-496, 1996 | 99 | 1996 |
| Ignition processes in carbon-monoxide-hydrogen-oxygen mixtures U Maas, J Warnatz Symposium (International) on combustion 22 (1), 1695-1704, 1989 | 98 | 1989 |
| Simple global reduction technique based on decomposition approach V Bykov, V Gol'Dshtein, U Maas Combustion Theory and Modelling 12 (2), 389-405, 2008 | 90 | 2008 |
