Symplectic embeddings of 4-dimensional ellipsoids into cubes

Abstract

Recently, McDuff and Schlenk determined the function cEB(a) whose value at a is the infimum of the size of a 4-ball into which the ellipsoid E(1,a) symplectically embeds (here, a >= 1 is the ratio of the area of the large axis to that of the smaller axis of the ellipsoid). In this paper we look at embeddings into four-dimensional cubes instead, and determine the function cEC(a) whose value at a is the infimum of the size of a 4-cube C4(A) = D2(A) times D2(A) into which the ellipsoid E(1,a) symplectically embeds (where D2(A) denotes the disc in mathbbR2 of area A). As in the case of embeddings into balls, the structure of the graph of cEC(a) is very rich: for a less than the square sigma2 of the silver ratio sigma := 1+sqrt(2), the function cEC(a) turns out to be piecewise linear, with an infinite staircase converging to (sigma2, sqrt(sigma2/2)). This staircase is determined by Pell numbers. On the interval [sigma2,7+1/32], the function cEC(a) coincides with the volume constraint sqrt(a/2) except on seven disjoint intervals, where c is piecewise linear. Finally, for a >= 7+1/32, the functions cEC(a) and sqrt(a/2) are equal. For the proof, we first translate the embedding problem E(1,a)-->C4(A) to a certain ball packing problem of the ball B4(2A). This embedding problem is then solved by adapting the method from McDuff-Schlenk, which finds all exceptional spheres in blow-ups of the complex projective plane that provide an embedding obstruction. We also prove that the ellipsoid E(1,a) symplectically embeds into the cube C4(A) if and only if E(1,a) symplectically embeds into the elllipsoid E(A,2A). Our embedding function cEC(a) thus also describes the smallest dilate of E(1,2) into which E(1,a) symplectically embeds.