Stable solution and extremal solution for fractional p-Laplacian

Abstract

To our knowledge, this paper is the first attempt to consider the existence issue for fractional p-Laplacian equation: (-)ps u= λ f(u),\; u> 0 ~in~;\; u=0\;in~ RN, where p>1, s∈ (0,1), λ>0 and is a bounded domain with C1, 1 boundary. We first propose a notion of stable solution, then we prove that when f is of class C1, nondecreasing and satisfying f(0)>0 and t ∞f(t)tp-1=∞, there exists an extremal parameter λ*∈ (0, ∞) such that a bounded minimal solution uλ ∈ W0s,p() exists if λ∈ (0, λ*), and no bounded solution exists if λ>λ*. Moreover, no W0s,p() solution exists for λ > λ* if in addition f(t)1p-1 is convex. To handle our problems, we show a Kato-type inequality for fractional p-Laplacian. We show also Lr estimates for the equation (-)psu=g with g∈ W0s, p()* Lq() for q ≥ 1, especially for q Nsp. We believe that these general results have their own interests. Finally, using the stability of minimal solutions uλ, under the polynomial growth or convexity assumption on f, we show that the extremal function u* =λλ*uλ ∈ W0s,p() in all dimensions, and u*∈ L∞() in some low dimensional cases.