Consider the following Neumann problem d△u- u + k(x)u^p = 0 and u 〉 0 in B1, δu/δv =0 on OB1,where d 〉 0, B1 is the unit ball in R^N, k(x) = k(|x|) ≠ 0 is nonnegative and in C(-↑B1), 1 〈 p 〈 N+2/N...Consider the following Neumann problem d△u- u + k(x)u^p = 0 and u 〉 0 in B1, δu/δv =0 on OB1,where d 〉 0, B1 is the unit ball in R^N, k(x) = k(|x|) ≠ 0 is nonnegative and in C(-↑B1), 1 〈 p 〈 N+2/N-2 with N≥ 3. It was shown in [2] that, for any d 〉 0, problem (*) has no nonconstant radially symmetric least energy solution if k(x) ≡ 1. By an implicit function theorem we prove that there is d0 〉 0 such that (*) has a unique radially symmetric least energy solution if d 〉 d0, this solution is constant if k(x) ≡ 1 and nonconstant if k(x) ≠ 1. In particular, for k(x) ≡ 1, do can be expressed explicitly.展开更多
基金the National Natural Science Foundation of China(No.10571174,10631030)Chinese Academy oF Sciences grant KJCX3-SYW-S03.
文摘Consider the following Neumann problem d△u- u + k(x)u^p = 0 and u 〉 0 in B1, δu/δv =0 on OB1,where d 〉 0, B1 is the unit ball in R^N, k(x) = k(|x|) ≠ 0 is nonnegative and in C(-↑B1), 1 〈 p 〈 N+2/N-2 with N≥ 3. It was shown in [2] that, for any d 〉 0, problem (*) has no nonconstant radially symmetric least energy solution if k(x) ≡ 1. By an implicit function theorem we prove that there is d0 〉 0 such that (*) has a unique radially symmetric least energy solution if d 〉 d0, this solution is constant if k(x) ≡ 1 and nonconstant if k(x) ≠ 1. In particular, for k(x) ≡ 1, do can be expressed explicitly.