We study the Max-Cut semidefinite programming (SDP) relaxation in the regime where a near-optimal solution admits a low-dimensional realization. While the Goemans--Williamson hyperplane rounding achieves the worst-case optimal approximation ratio αGW≈0.87856, it is natural to ask whether one can beat αGW when the SDP solution lives in Rd for a small dimension d. We answer this in the affirmative for every fixed d: there is a polynomial-time rounding algorithm that, given a d-dimensional feasible solution to the standard Max-Cut SDP strengthened with triangle inequalities, produces a cut of expected value at least (αGW+2−O(d)) times the SDP value. Our improvement is driven by a new geometric anti-concentration lemma for signs of low-dimensional Gaussian projections.