Properties of Normal Modes in a Modified Disordered Klein-Gordon Lattice: From Disorder to Order

Senyange, B.; Plessis, J.J. du; Manda, Bertin Many; Skokos, Ch.

doi:10.33581/1561-4085-2020-23-2-165-171

Cited by 4 publications

(2 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A single site excitation results to the excitation of several NMs, whose nonlinear interaction is responsible for the chaotic behavior of the wave-packet. As the spatial extent of the, nevertheless localized, NMs increases when W decreases [2,35,62], more NMs are excited by single site excitations for W = 4 than for W = 6. On top of that, the wider extent of these NMs lead to stronger interactions between them and in turn, to higher level of chaos as is observed in Fig.…”

Section: Aggregate Resultsmentioning

confidence: 99%

“…In the presence of nonlinearity the dynamics becomes more complicated as the system's normal modes (NMs) couple and chaos appears. Thus, the interplay of disorder and nonlinearity has attracted extensive attention in theory [12,13,14,15,16,17,18,19,20,21,22,23,24,25], numerical simulations [26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Identifying localized and spreading chaos in nonlinear disordered lattices by the Generalized Alignment Index (GALI) method

Senyange,

Skokos

2021

Preprint

View full text Add to dashboard Cite

Implementing the Generalized Alignment Index (GALI) method of chaos detection we investigate the dynamical behavior of the nonlinear disordered Klein-Gordon lattice chain in one spatial dimension. By performing extensive numerical simulations of single site and single mode initial excitations, for several disordered realizations and different disorder strengths, we determine the probability to observe chaotic behavior as the system is approaching its linear limit, i.e. when its total energy, which plays the role of the system's nonlinearity strength, decreases. We find that the percentage of chaotic cases diminishes as the energy decreases leading to exclusively regular motion on multidimensional tori. We also discriminate between localized and spreading chaos, with the former dominating the dynamics for lower energy values. In addition, our results show that single mode excitations lead to more chaotic behaviors for larger energies compared to single site excitations. Furthermore, we demonstrate how the GALI method can be efficiently used to determine a characteristic chaoticity time scale for the system when strong enough nonlinearites lead to energy delocalization in both the so-called 'weak' and 'strong chaos' spreading regimes.

show abstract

Section: Aggregate Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Identifying localized and spreading chaos in nonlinear disordered lattices by the Generalized Alignment Index (GALI) method

Senyange,

Skokos

2021

Preprint

View full text Add to dashboard Cite

show abstract

Identifying localized and spreading chaos in nonlinear disordered lattices by the Generalized Alignment Index (GALI) method

Senyange

Skokos

2022

Physica D: Nonlinear Phenomena

View full text Add to dashboard Cite

Frequency Map Analysis of Spatiotemporal Chaos in the Nonlinear Disordered Klein–Gordon Lattice

Skokos

Gerlach

Flach

2022

Int. J. Bifurcation Chaos

View full text Add to dashboard Cite

We study the characteristics of chaos evolution of initially localized energy excitations in the one-dimensional nonlinear disordered Klein–Gordon lattice of anharmonic oscillators, by computing the time variation of the fundamental frequencies of the motion of each oscillator. We focus our attention on the dynamics of the so-called “weak chaos” and “strong chaos” spreading regimes [Laptyeva et al., 2010], for which Anderson localization is destroyed, as the initially restricted excitation at the central region of the lattice propagates in time to more lattice sites. Based on the fact that large variations of the fundamental frequencies denote strong chaotic behavior, we show that in both regimes chaos is more intense at the central regions of the wave packet, where also the energy content is higher. On the other hand, the oscillators at the wave packet’s edges, through which the energy propagation happens, exhibit regular motion up until the time they gain enough energy to become part of the highly excited portion of the wave packet. Eventually, the percentage of chaotic oscillators remains practically constant, despite the fact that the number of excited sites grows as the wave packet spreads, but the portion of highly chaotic sites decreases in time. Thus, albeit the number of chaotic oscillators is constantly growing the strength of their chaotic behavior decreases, indicating that although chaos persists it is becoming weaker in time. We show that the extent of the zones of regular motion at the edges of the wave packet in the strong chaos regime is much smaller than in the weak chaos case. Furthermore, we find that in the strong chaos regime the chaotic component of the wave packet is not only more extended than in the weak chaos one, but in addition the fraction of strongly chaotic oscillators is much higher. Another important difference between the weak and strong chaos regimes is that in the latter case a significantly larger number of frequencies is excited, even from the first stages of the evolution. Moreover, our computations confirmed the shifting of fundamental frequencies outside the normal mode frequency band of the linear system in the case of the so-called “selftrapping” regime where a large part of the wave packet remains localized.

show abstract

Properties of Normal Modes in a Modified Disordered Klein-Gordon Lattice: From Disorder to Order

Cited by 4 publications

References 26 publications

Identifying localized and spreading chaos in nonlinear disordered lattices by the Generalized Alignment Index (GALI) method

Identifying localized and spreading chaos in nonlinear disordered lattices by the Generalized Alignment Index (GALI) method

Identifying localized and spreading chaos in nonlinear disordered lattices by the Generalized Alignment Index (GALI) method

Frequency Map Analysis of Spatiotemporal Chaos in the Nonlinear Disordered Klein–Gordon Lattice

Contact Info

Product

Resources

About