Long-time Asymptotics for the Ablowitz-Ladik system with present of solitons
Abstract
We investigate the soliton resolution and Painlev\'e asymptotics for the focusing Ablowitz-Ladik system with the initial data in a discrete weighted 2 space. First, we establish the global well-posedness of this initial-value problem, which is further reformulated as a Riemann-Hilbert problem with higher-order poles. Using Fredholm theory, the Riemann-Hilbert problem with the jump contour consisting of three circles centered around the origin is uniquely solved. Then, by performing a ∂-nonlinear steepest descent method to the Riemann-Hilbert problem, we obtain the asymptotic approximation to the solution of the focusing Ablowitz-Ladik system for large time in different space-time regions of the (n,t)-half plane. In the sectors \(n,t): n /(2t) <-M0 \ and \(n,t): n /(2t) >M0 \, where M0 is a positive constant, the leading order asymptotics is dominated by the solitons; while in the sector \(n,t): |n /(2t) -1 <M0-1 \, the long-time asymptotics is influenced by both the solitons and the oscillations; In the two transition zones \(n,t): |n /(2t)+1|t2/3 <C \ and \(n,t): |n /(2t)-1|t2/3 <C \ with C being a positive constant, we find the Painlev\'e-type asymptotics which can be expressed in terms of the solution of the second Painlev\'e transcendents.
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