On Mahler's conjecture for even s-concave functions in dimensions 1 and 2
Abstract
In this paper, we establish different sharp forms of Mahler's conjecture for s-concave even functions in dimensions n, for n=1 and 2, for s>-1/n, thus generalizing our previous results in FN on log-concave even functions in dimension 2, which corresponds to the case s=0. The functional volume product of an even s-concave function g is \[ ∫Rng(x)dx∫RnLsg(y)dy, \] where Lsg is the s-polar function associated to g. The analogue of Mahler's conjecture for even s-concave functions postulates that this quantity is minimized for the indicatrix of a cube for any s>-1/n. In dimension n=1, we prove this conjecture for all s∈(-1,0) (the case s0 was established by the first author and Mathieu Meyer in [page 17]FM10). In dimension n=2, we only consider the case 1/s∈Z: for s>0, we establish Mahler's conjecture for general s-concave even functions; for s<0, the situation is more involved, we only prove a sharp inequality for s-concave functions g such that gs admits an asymptote in every direction. Notice that this set of functions is quite natural to consider, when s<0, since it is the largest subset of s-concave functions stable by s-duality.
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