Self-Organized Multifrequency Clusters in an Oscillating Electrochemical System with Strong Nonlinear Coupling
Maximilian Patzauer, Katharina Krischer
Abstract
We study the spatiotemporal dynamics of the oscillatory photoelectrodissolution of n-type Si in a fluoride-containing electrolyte under anodic potentials using in situ ellipsometric imaging. When lowering the illumination intensity stepwise, we successively observe uniform oscillations, modulated amplitude clusters, and the coexistence of multifrequency clusters, i.e., regions with different frequencies, with a stationary domain. We argue that the multifrequency clusters emerge due to an adaptive, nonlinear, and nonlocal coupling, similar to those found in the context of neural dynamics.
Topics & Concepts
Coupling (piping)Context (archaeology)Nonlinear systemElectrolyteAmplitudeChemical physicsFrequency domainMaterials sciencePhysicsElectrochemistryMolecular physicsElectrodeOpticsQuantum mechanicsComputer scienceMetallurgyBiologyComputer visionPaleontologyNonlinear Dynamics and Pattern FormationNeural dynamics and brain functionPhotoreceptor and optogenetics research