2015
DOI: 10.3934/dcds.2015.35.3585
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On the blow-up results for a class of strongly perturbed semilinear heat equations

Abstract: We construct a solution for a class of strongly perturbed semilinear heat equations which blows up in finite time with a prescribed blow-up profile. The construction relies on the reduction of the problem to a finite dimensional one and the use of index theory to conclude.

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Cited by 16 publications
(39 citation statements)
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“…For parabolic equations, it has been used in [MZ08] and [Zaa01] for the Complex Ginzburg Landau (CGL) equation with no gradient structure, the critical harmonic heat flow in [RS13], the two dimensional Keller-Segel equation in [RS14] and the nonlinear heat equation involving nonlinear gradient term in [EZ11] and [TZ15]. Recently, this method has been applied for a non variational parabolic system in [NZ15b] for a logarithmically perturbed nonlinear equation in [NZ15a].…”
Section: Remark 14mentioning
confidence: 99%
“…For parabolic equations, it has been used in [MZ08] and [Zaa01] for the Complex Ginzburg Landau (CGL) equation with no gradient structure, the critical harmonic heat flow in [RS13], the two dimensional Keller-Segel equation in [RS14] and the nonlinear heat equation involving nonlinear gradient term in [EZ11] and [TZ15]. Recently, this method has been applied for a non variational parabolic system in [NZ15b] for a logarithmically perturbed nonlinear equation in [NZ15a].…”
Section: Remark 14mentioning
confidence: 99%
“…Note also that in [12], the corresponding construction was done with ζ 0 = 0. Accordingly estimate (24) in [12] was satisfied with ζ 0 = 0 and φ 1,0 = 0. Here lays a major difference between our approach and that of [12], in the sense that we construct our solution in relation with (ζ i (s 0 ) + ζ 0 ) i , which is a particular solution of (12), whereas in [12], the construction is done only for ζ 0 = 0.…”
Section: Construction Of a Multi-soliton Solution In Similarity Variamentioning
confidence: 99%
“…By the way, the proof of (43) is far from being easy. Here, since we work with any ζ 0 ∈ Ê (see (24)) and aim at prescribing the center of mass, we don't need to be that accurate, and from this point of view, our proof is more simple than the proof of [12].…”
Section: Let Us Apply This Proposition Withmentioning
confidence: 99%
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“…This two-step procedure has been successfully applied for various nonlinear evolution equations to construct both Type I and Type II blowup solutions. It was the case of the semilinear heat equation treated in [4], [32], [36] (see also [35], [9] for the case of logarithmic perturbations, [2], [3] and [16] for the exponential source, [37] for the complex-valued case), the Ginzburg-Landau equation in [27], [38] (see also [48] for an earlier work). It was also the nonlinear Schrödinger equation both in the mass critical [28,29,30,31] and mass supercritical [34] cases; the energy critical [10], [22] and supercritical [6] wave equation; the mass critical gKdV equation [24,25,26]; the two dimensional Keller-Segel model [42]; the energy critical and supercritical geometric equations: the wave maps [39] and [18], the Schrödinger maps [33] and the harmonic heat flow [40,41] and [17]; the semilinear heat equation in the energy critical [43] and supercritical [5] cases.…”
Section: Introductionmentioning
confidence: 99%