An introduction to nonlinear chemical dynamics: oscillations, waves, patterns, and chaos IR Epstein, JA Pojman Oxford university press, 1998 | 1886 | 1998 |
Modeling of turing structures in the chlorite—iodide—malonic acid—starch reaction system I Lengyel, IR Epstein Science 251 (4994), 650-652, 1991 | 630 | 1991 |
Nonlinear chemical dynamics: oscillations, patterns, and chaos IR Epstein, K Showalter The Journal of Physical Chemistry 100 (31), 13132-13147, 1996 | 594 | 1996 |
Systematic design of chemical oscillators. Part 13. Complex periodic and aperiodic oscillation in the chlorite-thiosulfate reaction M Orban, IR Epstein The Journal of Physical Chemistry 86 (20), 3907-3910, 1982 | 394* | 1982 |
A chemical approach to designing Turing patterns in reaction-diffusion systems. I Lengyel, IR Epstein Proceedings of the National Academy of Sciences 89 (9), 3977-3979, 1992 | 391 | 1992 |
Changing the culture of science education at research universities WA Anderson, U Banerjee, CL Drennan, SCR Elgin, IR Epstein, ... Science 331 (6014), 152-153, 2011 | 356 | 2011 |
Oscillatory cluster patterns in a homogeneous chemical system with global feedback VK Vanag, L Yang, M Dolnik, AM Zhabotinsky, IR Epstein Nature 406 (6794), 389-391, 2000 | 355 | 2000 |
Pattern formation in a tunable medium: The Belousov-Zhabotinsky reaction in an aerosol OT microemulsion VK Vanag, IR Epstein Physical review letters 87 (22), 228301, 2001 | 346 | 2001 |
Inwardly rotating spiral waves in a reaction-diffusion system VK Vanag, IR Epstein Science 294 (5543), 835-837, 2001 | 334 | 2001 |
Cross-diffusion and pattern formation in reaction–diffusion systems VK Vanag, IR Epstein Physical Chemistry Chemical Physics 11 (6), 897-912, 2009 | 319 | 2009 |
Experimental and theoretical studies of a coupled chemical oscillator: phase death, multistability and in-phase and out-of-phase entrainment MF Crowley, IR Epstein The Journal of Physical Chemistry 93 (6), 2496-2502, 1989 | 274 | 1989 |
Cooperative and non-cooperative binding of large ligands to a finite one-dimensional lattice: a model for ligand-ougonucleotide interactions IR Epstein Biophysical chemistry 8 (4), 327-339, 1978 | 249 | 1978 |
Testing Turing’s theory of morphogenesis in chemical cells N Tompkins, N Li, C Girabawe, M Heymann, GB Ermentrout, IR Epstein, ... Proceedings of the National Academy of Sciences 111 (12), 4397-4402, 2014 | 232 | 2014 |
Convective effects on chemical waves. 1. Mechanisms and stability criteria JA Pojman, IR Epstein Journal of Physical Chemistry 94 (12), 4966-4972, 1990 | 231 | 1990 |
Oscillating chemical reactions IR Epstein, K Kustin, P De Kepper, M Orbán Scientific American 248 (3), 112-123, 1983 | 230 | 1983 |
Experimental and modeling study of oscillations in the chlorine dioxide-iodine-malonic acid reaction I Lengyel, G Rabai, IR Epstein Journal of the American Chemical Society 112 (25), 9104-9110, 1990 | 223 | 1990 |
Reaction–diffusion processes at the nano-and microscales IR Epstein, B Xu Nature nanotechnology 11 (4), 312-319, 2016 | 222 | 2016 |
Systematic design of chemical oscillators. Part 8. Batch oscillations and spatial wave patterns in chlorite oscillating systems P De Kepper, IR Epstein, K Kustin, M Orban The Journal of Physical Chemistry 86 (2), 170-171, 1982 | 218 | 1982 |
Optimization of robustness and connectivity in complex networks B Shargel, H Sayama, IR Epstein, Y Bar-Yam Physical review letters 90 (6), 068701, 2003 | 209 | 2003 |
Nonlinear chemical dynamics F Sagués, IR Epstein Dalton transactions, 1201-1217, 2003 | 206 | 2003 |