Istvan Lengyel
Istvan Lengyel
Research Fellow at Sabic Technology and Innovation
Verified email at sabic.com
Title
Cited by
Cited by
Year
Modeling of Turing Structures in the Chlorite—Iodide—Malonic Acid—Starch Reaction System
I Lengyel, IR Epstein
Science 251 (4994), 650-652, 1991
5371991
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
3081992
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
1811990
Systematic design of chemical oscillators. Part 65. Batch oscillation 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
1241990
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
1201996
Transient turing structures in a gradient-free closed system
I Lengyel, S Kádár, IR Epstein
Science 259 (5094), 493-495, 1993
1051993
Kinetics of iodine hydrolysis
I Lengyel, IR Epstein, K Kustin
Inorganic Chemistry 32 (25), 5880-5882, 1993
1021993
Quasi-two-dimensional Turing patterns in an imposed gradient
I Lengyel, S Kádár, IR Epstein
Physical review letters 69 (18), 2729, 1992
701992
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
511997
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
391992
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
391991
Turing structures in simple chemical reactions
I Lengyel, IR Epstein
Accounts of chemical research 26 (5), 235-240, 1993
321993
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
312000
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
291988
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
281992
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
272004
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
261991
Turing structures. Progress toward a room temperature, closed system
IR Epstein, I Lengyel
Physica D: Nonlinear Phenomena 84 (1-2), 1-11, 1995
211995
Modeling of transient Turing-type patterns in the closed chlorine dioxide-iodine-malonic acid-starch reaction system
S Kadar, I Lengyel, IR Epstein
The Journal of Physical Chemistry 99 (12), 4054-4058, 1995
211995
Kinetics and mechanism of autocatalytic oxidation of Fe (phen) 2+ 3 and Fe (bpy) 2+ 3 by nitric acid
I Lengyel, T Barna, G Bazsa
Journal of the Chemical Society, Faraday Transactions 1: Physical Chemistry …, 1988
211988
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Articles 1–20