\begin{document}$\alpha $\end{document} and \begin{document}$\beta $\end{document} increase synchronously within a certain range, the type I square patterns of the same wavelength are obtained in the two subsystems. When the coupling parameters \begin{document}$\alpha $\end{document} and \begin{document}$\beta $\end{document} increase asynchronously, the type I square pattern can evolve into the type II square pattern on the same spatial scale through phase transition. Then, the new subharmonic modes are generated, and the complicated superlattice square patterns are obtained due to the resonance between the two Turing modes in a short wavelength mode subsystem. The influence of coupling between two subsystems on the square pattern is investigated. When the type I square pattern of wavelength \begin{document}$\lambda $\end{document} emerges, the square pattern will quickly lose its stability in the short wavelength mode subsystem, since the coupling coefficient is equal to zero. Finally a new square pattern of wavelength \begin{document}$\lambda $\end{document}/N is formed. The type I square patterns of two subsystems successively evolve into the type II square patterns through the phase transition. The spots move relatively with the extension of simulation time, and a new mode is generated and forms three-wave resonance in two subsystems, and then the hexagonal pattern dominates the system. Our results also show that the type II square pattern spontaneously transforms into a hexagonal pattern."> - 必威体育下载

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    Li Xin-Zheng, Bai Zhan-Guo, Li Yan
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    • Abstract views:6243
    • PDF Downloads:55
    • Cited By:0
    Publishing process
    • Received Date:10 December 2018
    • Accepted Date:05 January 2019
    • Available Online:01 March 2019
    • Published Online:20 March 2019

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