Existence of normalized least-energy solutions to the stationary fractional NLS is established on a constrained L2-submanifold, shown to coincide with unconstrained ground states, yielding sharp global/blow-up thresholds and instability by blow-up for the time-dependent equation.
Normalized solutions to the mixed dispersion nonlinear Schr\"odinger equation in the mass critical and supercritical regime
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abstract
In this paper, we study the existence of solutions to the mixed dispersion nonlinear Schr\"odinger equation $$ \gamma \Delta ^2 u -\Delta u + \alpha u=|u|^{2 \sigma} u, \quad u \in H^2(\R^N), $$ under the constraint $$ \int_{\R^N}|u|^2 \, dx =c>0. $$ We assume $\gamma >0, N \geq 1, 4 \leq \sigma N < \frac{4N}{(N-4)^+}$, whereas the parameter $\alpha \in \R$ will appear as a Lagrange multiplier. Given $c \in \R^+$, we consider several questions including the existence of ground states, of positive solutions and the multiplicity of radial solutions. We also discuss the stability of the standing waves of the associated dispersive equation.
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math.AP 1years
2019 1verdicts
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Normalized ground states for the fractional nonlinear Schr\"{o}dinger equations
Existence of normalized least-energy solutions to the stationary fractional NLS is established on a constrained L2-submanifold, shown to coincide with unconstrained ground states, yielding sharp global/blow-up thresholds and instability by blow-up for the time-dependent equation.