| Predator–prey model with diffusion and indirect prey-taxis JI Tello, D Wrzosek Mathematical Models and Methods in Applied Sciences 26 (11), 2129-2162, 2016 | 141 | 2016 |
| Mathematical modelling of cancer invasion: the importance of cell–cell adhesion and cell–matrix adhesion MAJ Chaplain, M LACHOWICZ, Z SZYMAŃSKA, D Wrzosek Mathematical Models and Methods in Applied Sciences 21 (04), 719-743, 2011 | 132 | 2011 |
| Global attractor for a chemotaxis model with prevention of overcrowding D Wrzosek Nonlinear Analysis: Theory, Methods & Applications 59 (8), 1293-1310, 2004 | 102 | 2004 |
| Long-time behaviour of solutions to a chemotaxis model with volume-filling effect D Wrzosek Proceedings of the Royal Society of Edinburgh Section A: Mathematics 136 (2 …, 2006 | 89 | 2006 |
| Existence of solutions for the discrete coagulation-fragmentation model with diffusion D Wrzosek | 80 | 1997 |
| On the Oort--Hulst--Safronov Coagulation Equation and Its Relation to the Smoluchowski Equation M Lachowicz, P Laurençot, D Wrzosek SIAM journal on mathematical analysis 34 (6), 1399-1421, 2003 | 68 | 2003 |
| The discrete coagulation equations with collisional breakage P Laurençot, D Wrzosek Journal of Statistical Physics 104, 193-220, 2001 | 65 | 2001 |
| Global regularity versus infinite-time singularity formation in a chemotaxis model with volume-filling effect and degenerate diffusion ZA Wang, M Winkler, D Wrzosek SIAM Journal on mathematical analysis 44 (5), 3502-3525, 2012 | 61 | 2012 |
| Nonlocal bilinear equations: Equilibrium solutions and diffusive limit M Lachowicz, D Wrzosek Mathematical Models and Methods in Applied Sciences 11 (08), 1393-1409, 2001 | 58 | 2001 |
| Mass-conserving solutions to the discrete coagulation–fragmentation model with diffusion D Wrzosek Nonlinear Analysis: Theory, Methods & Applications 49 (3), 297-314, 2002 | 56 | 2002 |
| On an infinite system of reaction-diffusion equations P Bénilan, D Wrzosek Advances in Mathematical Sciences and Applications 7, 351-366, 1997 | 55 | 1997 |
| Predation‐Mediated Coexistence of Large‐ and Small‐Bodied Daphnia at Different Food Levels ZM Gliwicz, D Wrzosek The American Naturalist 172 (3), 358-374, 2008 | 54 | 2008 |
| A chemotaxis model with threshold density and degenerate diffusion P Laurençot, D Wrzosek Nonlinear Elliptic and Parabolic Problems: A Special Tribute to the Work of …, 2005 | 54 | 2005 |
| Volume filling effect in modelling chemotaxis D Wrzosek Mathematical Modelling of Natural Phenomena 5 (1), 123-147, 2010 | 48 | 2010 |
| Limit cycles in predator-prey models DM Wrzosek Mathematical biosciences 98 (1), 1-12, 1990 | 40 | 1990 |
| A nonlocal coagulation-fragmentation model M Lachowicz, D Wrzosek Applicationes Mathematicae 27 (1), 45-66, 2000 | 38 | 2000 |
| Sol–gel transition in a coagulation–diffusion model MA Herrero, JJL Velázquez, D Wrzosek Physica D: Nonlinear Phenomena 141 (3-4), 221-247, 2000 | 33 | 2000 |
| The Becker–Döring Model with Diffusion II. Long Time Behavior P Laurençot, D Wrzosek Journal of differential equations 148 (2), 268-291, 1998 | 32* | 1998 |
| Singularity formation in chemotaxis systems with volume-filling effect ZA Wang, M Winkler, D Wrzosek Nonlinearity 24 (12), 3279, 2011 | 28 | 2011 |
| Model of chemotaxis with threshold density and singular diffusion D Wrzosek Nonlinear Analysis: Theory, Methods & Applications 73 (2), 338-349, 2010 | 28 | 2010 |
Miroslaw LachowiczProfessor of Mathematics, University of WarsawDirección de correo verificada de mimuw.edu.pl
