Self-similar blow-up solutions for the supercritical parabolic Hardy-H\'enon equation
Abstract
We classify the self-similar solutions presenting finite time blow-up to the parabolic Hardy-H\'enon equation ∂tu= u+|x|σup, (x,t)∈RN×(0,∞), in dimension N≥3 and the range of exponents σ∈(-2,∞), p>pS(σ):=N+2σ+2N-2. We establish the existence of self-similar blow-up solutions for any p>pS(σ), provided σ≥2. Moreover, we prove that, if k is any natural number and σ≥ 4k-2, the parabolic Hardy-H\'enon equation has at least k different self-similar blow-up solutions for any p>pS(σ). These results are in a stark contrast with the standard reaction-diffusion equation ∂tu= u+up, (x,t)∈RN×(0,∞), for which non-existence of any self-similar solution has been established, provided p overpasses the Lepin exponent pL:=1+6N-10, N≥11. For σ∈(-2,2), we derive the expression of generalized Lepin exponents pL(σ) for σ∈(0,2), respectively pL(σ) for σ∈(-2,0), and prove existence of self-similar solutions with finite time blow-up for p∈(pS(σ),pL(σ)), respectively p∈(pS(σ),pL(σ)). Numerical evidence of the optimality of these exponents is also included.
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