Early time evolution of a localized nonlinear excitation in the -FPUT chain
Abstract
We present the detailed dynamics of the particles in the -Fermi–Pasta–Ulam–Tsingou (FPUT) chain after the initiation of a localized nonlinear excitation (LNE) by squeezing a central bond in the monodispersed chain at time = 0 while all other particles remain in their original relaxed positions. In the absence of phonons in the system, the LNE appears to initiate its relaxation process by symmetrically emitting two very weak solitary waves. The next stage involves the spreading of the LNE and the formation of nonsolitary wave-like objects to broaden the excitation region until a stage is reached when many weak solitary wave-like objects can be emitted as the system begins its journey to quasi-equilibrium and then to equilibrium. In addition to being of fundamental interest, these systems may be realized using cantilever systems and could well hold the key to constructing the next generation of broadband energy harvesting systems.
Calculations and analyses have been performed by Kashyap and Westley. Datta was involved in the code development and the theory work. Sen was involved in designing the study and in the analyses of the results. All four authors participated in writing the manuscript.
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