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Updated: May 27, 2025

Excitonic Hamiltonians for Calculating Optical Absorption Spectra and Optoelectronic Properties of Molecular Aggregates and Solids
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Explosive transition in adaptive Stuart-Landau oscillators with higher-order interactions.

Umesh Kumar Verma1

  • 1Central University of Rajasthan, Department of Physics, Ajmer 305 817, India.

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|February 20, 2025
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Summary
This summary is machine-generated.

Adaptive coupling in nonidentical Stuart-Landau oscillators can cause explosive synchronization and transitions to death states, unlike simpler coupling methods. These findings offer new insights into complex system dynamics.

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Area of Science:

  • Complex Systems
  • Nonlinear Dynamics
  • Network Science

Background:

  • Nonidentical Stuart-Landau oscillators are fundamental models for studying synchronization phenomena.
  • Understanding transitions to synchronization and death states is crucial in various dynamical systems.
  • Higher-order interactions and adaptive coupling introduce complex behaviors not captured by pairwise coupling alone.

Purpose of the Study:

  • To investigate the impact of adaptive coupling and higher-order interactions on the synchronization and death states of nonidentical Stuart-Landau oscillators.
  • To compare the dynamics resulting from pairwise versus higher-order interactions under adaptive coupling.
  • To explore the influence of coupling strength and network structure (global vs. random) on these transitions.

Main Methods:

  • Simulations of nonidentical Stuart-Landau oscillators with adaptive pairwise and higher-order coupling.
  • Analysis of transition types (continuous vs. explosive) to synchronization and death states.
  • Extension of analysis to random network topologies.

Main Results:

  • Global coupling with higher-order interactions leads to asynchronous oscillations.
  • Pairwise interactions show a continuous transition to synchronization, which becomes explosive with adaptation.
  • Combined pairwise and higher-order interactions with adaptation result in explosive synchronization and transitions to death states.
  • Similar dynamics are observed in random networks.

Conclusions:

  • Adaptive coupling significantly alters synchronization dynamics, promoting explosive transitions.
  • The interplay between interaction order (pairwise vs. higher-order) and adaptation is critical in determining system behavior.
  • Findings provide insights into synchronization in complex networks, consistent with Kuramoto oscillator models.