An improved lower bound on the Banach--Mazur distance to the cross-polytope

Abstract

Let be an n× m matrix with independent standard Gaussian entries and let Gm = (B1m) be the associated Gaussian Gluskin polytope (equivalently, a random n-dimensional quotient of 1m). In the regime m = n3 we prove that, with probability at least 1-2/n, dBM(Gm,B1n) c n4/7( n)-C, where B1n = \ e1,…, en\ is the cross-polytope. This improves the previously best-known exponent 5/9 (up to logarithmic factors) for this Gaussian model; in particular, the same lower bound holds for K dBM(K,B1n). The main new ingredient is a conditioning-compatible treatment of the regime of ``many small-coefficients''. After passing to a suitable Gaussian quotient, we apply a Maurey-type sparsification that reduces the relevant entropy (in effect shrinking the support size from k to k/(n)) at the cost of a Euclidean thickening. We control this enlargement via a Gaussian measure bound stable under Euclidean thickening. In the complementary regime of ``few small-coefficients'', we give a streamlined argument avoiding the global tilting step in earlier work. Together these ingredients rebalance entropy and small-ball estimates and yield the exponent 4/7.