2022 - Research.com Engineering and Technology in Germany Leader Award
His main research concerns Statistical physics, Control theory, Topology, Bifurcation and Semiconductor. His Statistical physics study incorporates themes from Chaotic, Lorenz system, Coupling strength and Scaling. His study in the fields of Time delayed under the domain of Control theory overlaps with other disciplines such as Noise induced.
The study incorporates disciplines such as Artificial neural network, Master stability function, Network topology, Complex system and Eigenvalues and eigenvectors in addition to Topology. His study in Bifurcation is interdisciplinary in nature, drawing from both Mechanics and Classical mechanics. His studies in Semiconductor integrate themes in fields like Quantum dot, Kinetic Monte Carlo and Condensed matter physics.
His primary areas of investigation include Condensed matter physics, Topology, Control theory, Statistical physics and Nonlinear system. His Condensed matter physics study integrates concerns from other disciplines, such as Quantum dot, Electron and Electric field. His work is dedicated to discovering how Quantum dot, Quantum dot laser are connected with Scattering and other disciplines.
His Topology study combines topics in areas such as Network topology, Coupling strength and Synchronization. Control theory and Stability are frequently intertwined in his study. Nonlinear system and Semiconductor are commonly linked in his work.
Eckehard Schöll mainly focuses on Topology, Chimera, Coupling strength, Amplitude and Statistical physics. His Topology research is multidisciplinary, incorporating elements of Network topology, Phase, Relay and Synchronization. His work in Network topology covers topics such as Topology which are related to areas like Fitzhugh nagumo and Noise.
In his study, which falls under the umbrella issue of Noise, Nonlinear system is strongly linked to Kuramoto model. His work deals with themes such as Dynamical systems theory, Antipodal point, Stability and Cluster, which intersect with Phase. His Amplitude research includes elements of Eigenvalues and eigenvectors and Oscillation.
Eckehard Schöll spends much of his time researching Topology, Chimera, Amplitude, Statistical physics and Fractal. His research integrates issues of Phase, Artificial neural network, Van der Pol oscillator, Network topology and Feedback control in his study of Topology. His studies deal with areas such as Relay, Subnetwork, Oscillation and Bifurcation as well as Amplitude.
The various areas that he examines in his Statistical physics study include Airy function, Order of magnitude, Semiconductor laser theory, Nonlinear system and Transformation. The Quantum mechanics study combines topics in areas such as Lagrangian coherent structures and Chaotic oscillators. The concepts of his Control theory study are interwoven with issues in Moment closure, Noise, Stability and Coupling.
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Handbook of Chaos Control
Nonequilibrium Phase Transitions in Semiconductors: Self-Organization Induced by Generation and Recombination Processes
Experimental observation of chimeras in coupled-map lattices
Aaron M. Hagerstrom;Thomas E. Murphy;Rajarshi Roy;Philipp Hövel;Philipp Hövel.
Nature Physics (2012)
Loss of coherence in dynamical networks: spatial chaos and chimera states.
Iryna Omelchenko;Iryna Omelchenko;Yuri Maistrenko;Philipp Hövel;Eckehard Schöll.
Physical Review Letters (2011)
Nonequilibrium phase transitions in semiconductors
When nonlocal coupling between oscillators becomes stronger: patched synchrony or multichimera states.
Iryna Omelchenko;Oleh E. Omel’chenko;Philipp Hövel;Eckehard Schöll.
Physical Review Letters (2013)
Chimera Death: Symmetry Breaking in Dynamical Networks
Anna Zakharova;Marie Kapeller;Eckehard Schöll.
Physical Review Letters (2014)
Nonlinear Spatio-Temporal Dynamics and Chaos in Semiconductors
The Physics of Instabilities in Solid State Electron Devices
Melvin P. Shaw;Vladimir V. Mitin;Eckehard Schöll;Harold L. Grubin.
Synchronization patterns and chimera states in complex networks: Interplay of topology and dynamics
European Physical Journal-special Topics (2016)
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