Copyright © 2012 American Physical SocietyA scroll wave in a sufficiently thin layer of an excitable medium with negative filament tension can be stable nevertheless due to filament rigidity. Above a certain critical thickness of the medium, such scroll wave will have a tendency to deform into a buckled, precessing state. Experimentally this will be seen as meandering of the spiral wave on the surface, the amplitude of which grows with the thickness of the layer, until a break-up to scroll wave turbulence happens. We present a simplified theory for this phenomenon and illustrate it with numerical examples
Scroll waves are three-dimensional excitation patterns that rotate around a central filament curve; ...
Nonlinear waves of electrical excitation initiate cardiac contraction. Abnormal wave propagation in ...
One of the fundamental mechanisms for the onset of turbulence in 3D excitable media is negative fila...
A scroll wave in a sufficiently thin layer of an excitable medium with negative filament tension can...
Scroll waves in excitable media, described by the Barkley model, are studied. In the parameter regio...
Vortices in excitable media underlie dangerous cardiac arrhythmias. One way to eliminate them is by ...
Scroll waves are vortices that occur in three-dimensional excitable media. Scroll waves have been ob...
Scroll waves are vortices that occur in three-dimensional excitable media. Scroll waves have been ob...
Copyright © 2015 American Physical SocietyA scroll wave in a very thin layer of excitable medium is ...
Rotating spiral and scroll waves (vortices) are investigated in the FitzHugh-Nagumo model of excitab...
The mechanism of scroll wave turbulence is investigated in excitable media with rotational anisotrop...
This paper was subsequently published in Physical Review Letters vol. 119, article 258101 (DOI: http...
This is the author accepted manuscript. The final version is available from American Physical Societ...
Scroll waves in a three-dimensional media may develop into turbulence due to negative tension of the...
Rotating scroll waves are dynamical spatiotemporal structures characteristic of three-dimensional ac...
Scroll waves are three-dimensional excitation patterns that rotate around a central filament curve; ...
Nonlinear waves of electrical excitation initiate cardiac contraction. Abnormal wave propagation in ...
One of the fundamental mechanisms for the onset of turbulence in 3D excitable media is negative fila...
A scroll wave in a sufficiently thin layer of an excitable medium with negative filament tension can...
Scroll waves in excitable media, described by the Barkley model, are studied. In the parameter regio...
Vortices in excitable media underlie dangerous cardiac arrhythmias. One way to eliminate them is by ...
Scroll waves are vortices that occur in three-dimensional excitable media. Scroll waves have been ob...
Scroll waves are vortices that occur in three-dimensional excitable media. Scroll waves have been ob...
Copyright © 2015 American Physical SocietyA scroll wave in a very thin layer of excitable medium is ...
Rotating spiral and scroll waves (vortices) are investigated in the FitzHugh-Nagumo model of excitab...
The mechanism of scroll wave turbulence is investigated in excitable media with rotational anisotrop...
This paper was subsequently published in Physical Review Letters vol. 119, article 258101 (DOI: http...
This is the author accepted manuscript. The final version is available from American Physical Societ...
Scroll waves in a three-dimensional media may develop into turbulence due to negative tension of the...
Rotating scroll waves are dynamical spatiotemporal structures characteristic of three-dimensional ac...
Scroll waves are three-dimensional excitation patterns that rotate around a central filament curve; ...
Nonlinear waves of electrical excitation initiate cardiac contraction. Abnormal wave propagation in ...
One of the fundamental mechanisms for the onset of turbulence in 3D excitable media is negative fila...