Open AccessTopology-driven nonlinear switching in Möbius discrete arrays
Author(s) -
Francisco Muñoz,
Sergei K. Turitsyn,
Yuri S. Kivshar,
Mario Molina
Publication year - 2017
Publication title -
physical review. a/physical review, a
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.391
H-Index - 283
eISSN - 2469-9934
pISSN - 2469-9926
DOI - 10.1103/physreva.95.033833
Subject(s) - physics , coupling (piping) , topology (electrical circuits) , soliton , chain (unit) , nonlinear system , parameter space , phase (matter) , space (punctuation) , magnetic monopole , spectrum (functional analysis) , quantum mechanics , mathematics , computer science , geometry , combinatorics , materials science , metallurgy , operating system
We examine the switching dynamics of discrete solitons propagating along two coupled discrete arrays which are twisted to form a Mobius strip. We analyze the potential of the topological switches by comparing the differences between the Mobius strip and untwisted discrete arrays. We employ the Ablowitz-Ladik (AL) model and reveal a nontrivial Berry phase associated with the monopole spectra in parameter space. We study the dynamical evolution of the AL soliton launched into one of the chains and observe its switching behavior. While in the untwisted discrete case, the soliton splits in nearly identical portions as the interchain coupling is increased, in the Mobius case and for weak coupling, we observe a well-defined "switching time" where the soliton switches completely from one chain to the other.
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