Sine-Gordon solitons in networks: Scattering and transmission at vertices

Sobirov, Z. A.; Babajanov, D.; Matrasulov, D. U.; Nakamura, Katsuhiro; Uecker, Hannes

doi:10.1209/0295-5075/115/50002

Cited by 36 publications

(61 citation statements)

References 34 publications

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“…An extension of the method applied here to networks with the dynamics determined by the Burgers' equation, the Dirac equation with nonlinearity [25], Korteweg-de Vries [26], or the sine-Gordon equation [27] could lead to new insights into bifurcations present in these systems.…”

Section: Discussionmentioning

confidence: 99%

“…J r,e (x e )(1 − cos(β r,e (x e )))dx e (27) which at this stage is a function of φ 0 . The remaining matching condition e φ e ( e ) = 0 may be reduced to …”

Section: B Star Graphsmentioning

confidence: 99%

“…Equations (26), (27), and (28) implicitly define the spectral curves k n (N ). While they are simpler than the corresponding exact equations based on Jacobi elliptic functions, they generally remain nonlinear.…”

Section: B Star Graphsmentioning

confidence: 99%

“…Let us now turn to the three asymptotic regimes R1, R2, and R3 where additional simplifications allow for a more explicit form of the solutions. In the low-intensity regime R1 λ ∼ g|φ e | 2 /k 2 ∝ gI r /k 3 → 0 where κ = k is bounded one may expand oscillatory functions such as sin(k r,e e /2) and consider the leading-order corrections in the continuity condition (26), the total intensity (27), and the quantizations condition (28). In Appendix B, we show how these expansions can be used to find spectral curves k(N ) in the vicinity of the linear spectrum.…”

Section: B Star Graphsmentioning

confidence: 99%

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Stationary waves on nonlinear quantum graphs. II. Application of canonical perturbation theory in basic graph structures

Gnutzmann

Waltner

2016

Phys. Rev. E

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We consider exact and asymptotic solutions of the stationary cubic nonlinear Schrödinger equation on metric graphs. We focus on some basic example graphs. The asymptotic solutions are obtained using the canonical perturbation formalism developed in our earlier paper [S. Gnutzmann and D. Waltner, Phys. Rev. E 93, 032204 (2016)]. For closed example graphs (interval, ring, star graph, tadpole graph), we calculate spectral curves and show how the description of spectra reduces to known characteristic functions of linear quantum graphs in the low-intensity limit. Analogously for open examples, we show how nonlinear scattering of stationary waves arises and how it reduces to known linear scattering amplitudes at low intensities. In the short-wavelength asymptotics we discuss how genuine nonlinear effects may be described using the leading order of canonical perturbation theory: bifurcation of spectral curves (and the corresponding solutions) in closed graphs and multistability in open graphs.

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Section: Discussionmentioning

confidence: 99%

“…J r,e (x e )(1 − cos(β r,e (x e )))dx e (27) which at this stage is a function of φ 0 . The remaining matching condition e φ e ( e ) = 0 may be reduced to …”

Section: B Star Graphsmentioning

confidence: 99%

Section: B Star Graphsmentioning

confidence: 99%

Section: B Star Graphsmentioning

confidence: 99%

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Stationary waves on nonlinear quantum graphs. II. Application of canonical perturbation theory in basic graph structures

Gnutzmann

Waltner

2016

Phys. Rev. E

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“…This constraint was introduced in [25,26] as a condition of the reflectionless transmission of a solitary wave across the vertex of the star graph Γ. The time flow on Γ is given by the following nonlinear Schrödinger (NLS) equation:…”

Section: Resultsmentioning

confidence: 99%

Drift of Spectrally Stable Shifted States on Star Graphs

Kairzhan¹,

Pelinovsky²,

Goodman³

2019

SIAM J. Appl. Dyn. Syst.

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When the coefficients of the cubic terms match the coefficients in the boundary conditions at a vertex of a star graph and satisfy a certain constraint, the nonlinear Schrödinger (NLS) equation on the star graph can be transformed to the NLS equation on a real line. Such balanced star graphs have appeared in the context of reflectionless transmission of solitary waves. Steady states on such balanced star graphs can be translated along the edges with a translational parameter and are referred to as the shifted states. When the star graph has exactly one incoming edge and several outgoing edges, the steady states are spectrally stable if their monotonic tails are located on the outgoing edges. These spectrally stable states are degenerate minimizers of the action functional with the degeneracy due to the translational symmetry. Nonlinear stability of these spectrally stable states has been an open problem up to now. In this paper, we prove that these spectrally stable states are nonlinearly unstable because of the irreversible drift along the incoming edge towards the vertex of the star graph. When the shifted states reach the vertex as a result of the drift, they become saddle points of the action functional, in which case the nonlinear instability leads to their destruction. In addition to rigorous mathematical results, we use numerical simulations to illustrate the drift instability and destruction of the shifted states on the balanced star graph.

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Nonlinearity + Networks: A 2020 Vision

Porter

2020

Emerging Frontiers in Nonlinear Science

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Sine-Gordon solitons in networks: Scattering and transmission at vertices

Cited by 36 publications

References 34 publications

Stationary waves on nonlinear quantum graphs. II. Application of canonical perturbation theory in basic graph structures

Stationary waves on nonlinear quantum graphs. II. Application of canonical perturbation theory in basic graph structures

Drift of Spectrally Stable Shifted States on Star Graphs

Nonlinearity + Networks: A 2020 Vision

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