| Modeling of turing structures in the chlorite—iodide—malonic acid—starch reaction system I Lengyel, IR Epstein Science 251 (4994), 650-652, 1991 | 625 | 1991 |
| 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 | 385 | 1992 |
| 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 | 214 | 1990 |
| Rate constants for reactions between iodine-and chlorine-containing species: A detailed mechanism of the chlorine dioxide/chlorite-iodide reaction I Lengyel, J Li, K Kustin, IR Epstein Journal of the American Chemical Society 118 (15), 3708-3719, 1996 | 136 | 1996 |
| Kinetics of iodine hydrolysis I Lengyel, IR Epstein, K Kustin Inorganic chemistry 32 (25), 5880-5882, 1993 | 132 | 1993 |
| Batch oscillations in the reaction of chlorine dioxide with iodine and malonic acid I Lengyel, G Rabai, IR Epstein Journal of the American Chemical Society 112 (11), 4606-4607, 1990 | 117 | 1990 |
| Transient Turing structures in a gradient-free closed system I Lengyel, S Kadar, IR Epstein Science 259 (5094), 493-495, 1993 | 115 | 1993 |
| Quasi-two-dimensional Turing patterns in an imposed gradient I Lengyel, S Kádár, IR Epstein Physical review letters 69 (18), 2729, 1992 | 73 | 1992 |
| Computational chemistry predictions of reaction processes in organometallic vapor phase epitaxy H Simka, BG Willis, I Lengyel, KF Jensen Progress in crystal growth and characterization of materials 35 (2-4), 117-149, 1997 | 61 | 1997 |
| Diffusion‐induced instability in chemically reacting systems: Steady‐state multiplicity, oscillation, and chaos I Lengyel, IR Epstein Chaos: An Interdisciplinary Journal of Nonlinear Science 1 (1), 69-76, 1991 | 49 | 1991 |
| New systems for pattern formation studies IR Epstein, I Lengyel, S Kádár, M Kagan, M Yokoyama Physica A: Statistical Mechanics and its Applications 188 (1-3), 26-33, 1992 | 46 | 1992 |
| Turing structures in simple chemical reactions I Lengyel, IR Epstein Accounts of chemical research 26 (5), 235-240, 1993 | 42 | 1993 |
| A chemical mechanism for in situ boron doping during silicon chemical vapor deposition I Lengyel, KF Jensen Thin Solid Films 365 (2), 231-241, 2000 | 40 | 2000 |
| Kinetics and mechanism of autocatalytic oxidation of formaldehyde by nitric acid M Horváth, I Lengyel, G Bazsa International journal of chemical kinetics 20 (9), 687-697, 1988 | 38 | 1988 |
| Brine purification B Hook, D Tirtowidjojo, F Koester, SK Chaudhary, A Mehta, J Chauvel, ... US Patent 8,343,328, 2013 | 33 | 2013 |
| A computational study of gas-phase and surface reactions in deposition and etching of GaAs and AlAs in the presence of HCl C Cavallotti, I Lengyel, M Nemirovskaya, KF Jensen Journal of crystal growth 268 (1-2), 76-95, 2004 | 33 | 2004 |
| Catalyst ignition and extinction: A microkinetics-based bifurcation study of adiabatic reactors for oxidative coupling of methane LA Vandewalle, I Lengyel, DH West, KM Van Geem, GB Marin Chemical Engineering Science 199, 635-651, 2019 | 31 | 2019 |
| Silver promoted catalysts for oxidative coupling of methane W Liang, VSR Sarsani, D West, H Perez, A Mamedov, I Lengyel, J Lowrey US Patent 10,625,244, 2020 | 29 | 2020 |
| Systematic design of chemical oscillators. 82. Dynamical study of the chlorine dioxide-iodide open system oscillator I Lengyel, J Li, IR Epstein The Journal of Physical Chemistry 96 (17), 7032-7037, 1992 | 28 | 1992 |
| Systematic design of chemical oscillators. 72. A transition-metal oscillator: oscillatory oxidation of manganese (II) by periodate in a CSTR M Orban, I Lengyel, IR Epstein Journal of the American Chemical Society 113 (6), 1978-1982, 1991 | 27 | 1991 |
Irving R. EpsteinProfessor of Chemistry, Brandeis UniversityGeverifieerd e-mailadres voor brandeis.edu
