Chaos in chemistry and biochemistry

True deterministic chaos is characterized by unpredictable, apparently random motion in a dynamical system completely described by a deterministic dynamic law, usually a nonlinear differential equation, with no stochastic component. The inability to predict future behavior of a chaotic system occurs because trajectories evolving from arbitrarily close initial conditions diverge. Chaos is universal as it may arise in any system governed by one of a class of quite common, suitable nonlinear dynamic laws. This book discusses both the experimental observation and theoretical interpretation of chaos in chemical and biochemical systems. Examples are drawn from the Belousov-Zhabotinsky reaction, surface reactions, electrochemical reactions, enzyme reactions, and periodically perturbed oscillating systems.

• Mathematics of coupled and forced oscillators, W.R. Derrick
• experimental description of chaos in the Belousov-Zhabotinsky reaction, J-C. Roux
• modelling and interpretation of chaos in the Belousov-Zhabotinsky reaction, L. Gyorgyi
• chaos in forced and coupled chemical oscillators, M. Marek
• chaos in electrochemical systems, J. Hudson
• chaos in surface reactions, M. Eiswirth and C. Ertl
• chaos in biochemical systems - the peroxidase reaction as a case study, R. Larter
• from periodicity to chaos in biochemical systems, A. Goldbeter
• new theoretical approach for describing physico-chemical reaction dynamics with chaotic behaviour, V. Gontar.