Ulrich Storb scite author profile

Two kinds of scroll wave instabilities were studied experimentally in the excitable Belousov-Zhabotinsky reaction: three-dimensional meandering and negative line tension of the scroll wave filament. The filament displays a flat zigzag shape in the initial stages of the experiment. As the chemical medium ages, the filament assumes a wiggly shape while its length increases substantially. Numerical simulations underpin the experimental findings and their interpretation.

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An elegant method to study an isolated spiral wave in a thin layer of a batch Belousov–Zhabotinsky reaction under oxygen-free conditions

Luengviriya

Storb

Hauser

et al. 2006

Phys. Chem. Chem. Phys.

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A method to prepare a uniform thin layer of a batch Belousov-Zhabotinsky (BZ) reaction under oxygen-free conditions for the study of an isolated spiral wave is presented. After a first layer of gel soaked with the BZ solution has been delivered into the reactor, a single spiral wave was initiated, and finally the remaining reactor volume was filled with gel and BZ medium. The completely filled reactor is sealed gas-tightly, yielding oxygen-free, and thus more controlled, reaction conditions. A systematic study of the behaviour of an isolated spiral wave in a ferroin-catalyzed BZ reaction under batch conditions has been performed. Recipes for BZ media that support a slowly rotating meandering spiral were developed. In cases of extremely low excitability (i.e., relative large stimuli are required to induce a propagating wave), the number of petals in the trajectory of a spiral tip decreased due to aging of the reaction system. Since oxygen-free conditions are necessary for the study of the dynamics in three-dimensional excitable media, and the wave velocities of a spiral are sufficiently low, the developed chemical recipes are suitable for studies of the behaviour of scroll waves in three-dimensional systems by optical tomography.

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Spiral wave dynamics under feedback control derived from a variety of sensory domains

et al. 2004

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The dynamics of rigidly rotating spiral waves in a reaction layer with light-dependent excitability is studied by numerical integration of a reaction-diffusion equation system with a feedback control. The feedback signal is derived from sensory domains with different geometries by introducing an algorithm that computes the illumination intensity to be proportional to the average wave activity in these domains. It is shown that the shape and size of the trajectories of the spiral wave tip as well as the stability of the spiral rotation depend sensitively on the choice of the geometry of the sensory domain. The numerically observed effects are complemented by constructing a flow map based on an analysis of the feedback signal.

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A Synergetic Approach to Describe the Stability and Variability of Motor Behavior

Witte¹,

Bock²,

Storb³

et al. 2003

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Ulrich Storb

A tomographic study of desynchronization and complex dynamics of scroll waves in an excitable chemical reaction with a gradient

Scroll Wave Instabilities in an Excitable Chemical Medium

An elegant method to study an isolated spiral wave in a thin layer of a batch Belousov–Zhabotinsky reaction under oxygen-free conditions

Spiral wave dynamics under feedback control derived from a variety of sensory domains

A Synergetic Approach to Describe the Stability and Variability of Motor Behavior

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