On semilinear elliptic equations with nonlocal nonlinearity

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On semilinear elliptic equations with nonlocal nonlinearity Shinji Kawano Department of Mathematics Hokkaido University Sapporo 060-0810, Japan Abstract We consider the problem 8 < A A + A p ka A 2 dx = 0 in, : lim A(x) = 0, where p > 1, k > 0 are constants. We classify the existence of all possible positive solutions to this problem. 1 Introduction Equations with nonlocal nonlinearity arise in the study of pattern formation in various fields of science such as fluid mechanics as well as chemistry or biology. Especially iecke [12] has suggested the following equation: A t = A + µa + c A 2 A A 4 A k A 2 dx, (1) where A is a complex-valued function defined on (0, ), k > 0 and c, µ are real numbers. We are interested in positive solutions. This means that we replace (1) by the following equation: A t = A + µa + ca 3 A 5 ka A 2 dx, (2) where A is a positive function defined on (0, ). Wei and Winter [13] studied this eequation (2), together with the steadystate solutions of (2) which satisfy A + µa + ca 3 A 5 ka A 2 dx = 0. (3) 1

They have classified the existence of positive solutions to (3) and studied the stability of all possive standing wave solutions. For other researches for equations concerned with pattern formation, consult Matthews and Cox [7] and Norbury, Wei and Winter [9]. In this present paper, we shall consider the following problem A A + A p ka A 2 dx = 0 in, n lim A(x) = 0, A(0) = max A(x), (4) x where A is a positive-valued function defined on (0, ) and p > 1, k > 0 are constants, n is the space dimension n 1, integer. This equation is from (3), modified and generalized to seize mathematical structures. We shall find classical positive solutions to (4), using the uniqueness result to single power nonlinear equation given by Kwong [5]. Following is the main result of the present paper: Theorem 1. For any p (0, p (n)), the problem (4) has a positive radially symmetric solution if k > 0 is sufficiently small. For any p [p (n), ), the problem (4) does not have any solutions for any k > 0. Here, p (n) is the exponent called Sobolev exponent defined by the following formula: n = 1, 2. p (n) = n + 2 n 3. n 2 In the next section we present the proof of the theorem and more detailed formulation of the theorem. We note here that the method is essentially based on Wei and Winter [13]. 2 Proof of the theorem First we state the key lemma for the proof. Lemma 1. Consider the problem A ωa + A p = 0, lim A(x) = 0, A(0) = max A(x), (5) x where p > 1 and ω > 0. 1. If 1 < p < p (n), the problem (5) posesses the unique positive radially symmetric classical solution for each ω > 0. Moreover, the solution A is given by the following formula: A(x) = ω 1 p 1 A0 ( ωx), (6) 2

where A 0 is the unique solution of the following problem: A A + A p = 0, lim A(x) = 0, A(0) = max A(x), (7) x (This problem (7) is the problem (5) with ω = 1.) 2. If p (n) p < the problem (5) does not have any positive solutions. 3. The function A 0 has exponential decay at infinity: for some C, δ > 0. A 0 (x) Ce δ x, x, Proof. The existence and non-existence part is due to the classical work of Pohozev [11]. The fact that for p p (n), (5) does not have any solution follows from a well known identity of Pohozaev. Also see Berestycki and Lions [1] and Berestycki, Lions and Peletier [2]. The decay rate of A 0 is studied in Berestycki and Lions [1]. The classical work of Gidas, Ni and Nirenberg [3, 4] tells us that all positive solutions are radially symmetric. The uniqueness result of (7) is by Kwong [5] for n 3, by Mcleod and Serrin [8] for n = 2, and by Berestycki and Lions [1] for n = 1. It is enough to prove uniqueness for (5) with any ω > 0, and the representation formula (6). A(x) defined by the formula (6) is a solution to the problem (5). On the other hand, for the solution B(x) to (5), B 0 (x) := ω 1 p 1 B( ω x ) is a solution to (7). By the uniqueness theorem for (7), this B 0 is equal to A 0 at any point. This fact completes the proof. First we note that the problem (4) is equivalent to A ωa + A p = 0, ω = 1 + k A 2 dx, n A(x) = 0, lim So the solution of (4) is of the form A(0) = max A(x). x A(x) = ω 1 p 1 A0 ( ωx), with the consistency condition ω = 1 + k ω 2 p 1 A0 ( ωx) 2 dx n = 1 + k ω 2 p 1 n 2 A0 (y) 2 dy. (8) 3

The relation (8) is equivalent to where kα = (ω 1)ω n 2 2 p 1, α = A 0 (y) 2 dy. Note that 0 < α < from the fact 3. of the Lemma 1. We analyze the function f(ω) := (ω 1)ω n 2 2 p 1. We define e n,p := n 2 2. Five cases occur when we investigate the function p 1 f(ω) in (0, ): 1 e n,p + 1 < 0 i.e. 1 < p < 1 + 4 f(ω) attains its maximum at ω n,p := the maximum is positive. f(+0) := lim ω 0 f(ω) =, 2 e n,p + 1 = 0 i.e. p = 1 + 4 f(ω) is increasing in (0, ). f(+0) =, f( ) = 1. 3 0 < e n,p + 1 < 1 i.e. 1 + 4 n + 2 < p < 1 + 4 n. f(ω) is increasing in (0, ). f(+0) =, f( ) =. 4 e n,p + 1 = 1 i.e. p = 1 + 4 n. f(ω) is increasing in (0, ). f(+0) = 1, f( ) =. 5 1 < e n,p + 1 i.e. 1 + 4 n < p. f(ω) attains its minimum at ω n,p = minimum is negative. f(+0) = 0, f( ) =. Following is the detailed statement of the theorem: e n,p e n,p 1 > 0, and f( ) := lim f(ω) = 0. ω e n,p e n,p + 1 > 0, and the 4

Theorem 2. Let the space dimension n 1 be fixed. 1 1 < p < 1 + 4 1-1 If k > f(ω n,p), then the problem (4) does not have any solution. α 1-2 If k = f(ω n,p), then the problem (4) has exactly one solution. α f(ω n,p ) 1-3 If > k > 0, then the problem (4) has two solutions. α 2 p = 1 + 4 2-1 If k 1, then the problem (4) does not have any solution. 2-2 If 0 < k < 1, then the problem (4) has exactly one solution. 3 1 + 4 n + 2 < p < p (n). 3-1 For any k > 0, the problem (4) has exactly one solution. 4 p (n) p. 4-1 For any k > 0, the problem (4) does not have any solution. Here a solution means a positive radial symmetric classical solution. Proof of Theorem 2. For p p (n). Suppose there is a solution A(x), for contradidtion. Then A is a solution of with A ωa + A p = 0 (9) ω := 1 + k A 2 dx. (10) This contradicts to the fact 2. of the Lemma 1. From now on we concentrate on the case 1 < p < p (n). Lemma 2. Suppose that for k > 0, there exists ω > 0 such that f(ω) = kα. Then A(x) := ω 1 p 1 A0 ( ωx) is a solution to (4). On the other hand, for a solution A(x) of (4) with k > 0, there exists ω > 0 such that f(ω) = kα. Moreover, A is formulated with this ω: A(x) = ω 1 p 1 A0 ( ωx). Proof. First remember that for A(x) := ω 1 p 1 A0 ( ωx), f(ω) = kα is equivalent to 1 + A 2 dx = ω. 5

Now we prove the first statement. The left hand side of the equation in problem (4) is calculated in the following way: ( ) A A + A p ka A 2 dx = A 1 + A 2 dx A + A p = A ωa + A p = 0. Then we prove the last statement. A solution A of (4) is a solution of (9) with (10). Here ω has to be positive, for otherwise the equation (9) cannot have any solution. From (9) comes the formula A(x) = ω 1 p 1 A0 ( ωx), and the relation f(ω) = kα is from (10). The above lemma and the observation of the graph of f(u) completes the proof of Theorem 2. emark 1. Note that any solution of our problem (4) is in the form (6): these solutions converges to A 0 pointwise as k in (4) goes to zero. emark 2. We can treat a more generalized problem in the same way: A A + A p ka A r dx = 0 in, n lim A(x) = 0, A(0) = max A(x), x where r is positive. We need three cases to be dealt with if n 3: 0 < r < 2n n 2, 2n 2(n + 2) r < n 2 n 2, 2(n + 2) r. n 2 Our r = 2 is always in the first case, which is most bothersome. We shall omit the full observation. eferences [1] H. Berestycki and P. L. Lions, Nonlinear scalar field equation, I., Arch. at. Meth. Anal. 82 (1983), 313-345. [2] H. Berestycki, P. L. Lions and L. A. Peletier, An ODE approach to the existence of positive solutions for semilinear problems in N, Indiana University Math. J. 30 (1981), 141-157. [3] B. Gidas, W. M. Ni and L. Nirenberg, Symmetry and related properties via the maximal principle, Comm. Math. Phys. 68 (1979), 209-243. [4] B. Gidas, W. M. Ni and L. Nirenberg, Symmetry of positive solutions of nonlinear elliptic equations in, Mathematical analysis and applications, Part A, Adv. in Math. Suppl. stud. 7a, Academic press, 1981, 369-402. 6

[5] M. K. Kwong, Uniqueness of positive solutions of u u + u p = 0 in, Arch. ational Mech. Anal. 105 (1989), 243-266. [6] M. K. Kwong and L. Zhang, Uniqueness of positive solutions of u+f(u) = 0 in an annulus, Differential Integral Equations 4 (1991), 583-599. [7] P. C. Matthews and S. M. Cox, Pattern formation with a conservation law, Nonlinearity 13, (2000), 1293-1320. [8] K. McLeod and J. Serrin, Uniqueness of positive radial solutions of u + f(u) = 0 in, Arch. ational. Mech. Anal. 99 (1987), 115-145. [9] J. Norbury, J. Wei and M. Winter, Existence and stability of singular patterns in a Ginzburg-Landau equation coupled with a mean field, Nonlinearity 15 (2002), 2077-2096. [10] T. Ouyang and J. Shi, Exact multiplicity of positive solutions for a class of semilinear problems, J. Differential Equations 146 (1998), 121-156. [11] S. I. Pohozaev, Eigenfunctions of the equation u + λf(u) = 0, Sov. Math. Doklady 5 (1965), 1408-1411. [12] H. iecke, Localized structures in pattern-forming systems, in Pattern formation in continuous and and coupled systems (Mineapolis, MN, 1998), 215-229, IMA Vol. Math. Appl. 115, Springer, New York, 1999. [13] J. Wei and M. Winter, On a cubic-quintic Ginzburg-Landau equation with global coupling, Proc. Amer. Math. Soc. 133 (2005), 1787-1796. 7

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