Ground states of the Schr\"odinger equation coupled with fourth-order gravitation -- Part 1: the case Ka, b ≤ 0
Abstract
We are interested in the existence and asymptotic behavior of ground states of the following normalized nonlocal semilinear problem: \[ cases - u + (V - ω) u + (Ka, b u2) u = 0 &in ~ R3; \\ \|u\|L22 = μ, cases \] where \[ Ka, b (x) := 1|x| ( 43 e- b |x| - 13 e- a |x| - 1 ); \] 0 ≤ a, b ≤ ∞; V denotes a singular potential that vanishes at infinity and the unknowns are ω ∈ R, u R3 R. This problem is obtained by looking for standing waves of the Schr\"odinger equation coupled with the nonrelativistic gravitational potential prescribed by a family of fourth-order gravity theories. In this paper, (i) we obtain a complete picture of the existence/nonexistence of ground states of the associated autonomous problem for every possible geometry of Ka, b, (ii) we obtain conditions that ensure the existence of ground states of the nonautonomous problem when Ka, b ≤ 0 and (iii) we prove that as \[ (a, b) (A, B) ∈ \(0, 0), (∞, ∞), (0, ∞)\, \] ground states of this problem respectively converge to a ground state of (1) the Schr\"odinger equation, (2) the Choquard equation and (3) a rescaling of the Choquard equation.
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