Three self-similar solutions of Yang-Mills equations in high odd dimensions

Abstract

We consider spherically symmetric Yang-Mills equations with gauge group SO(d) in d+1 dimensional Minkowski spacetime. For any given odd d≥ 11, we establish existence and uniqueness (modulo reflection symmetry) of exactly N smooth self-similar solutions, where N is the number of zeros of an explicit polynomial Pm(z) of degree m=(d-5)/2 in the interval 0<z<1. The number N can be determined algorithmically by an explicit computation. Our extensive computations for large odd dimensions suggest that N=3 for all odd d≥ 11. Two of these self-similar solutions admit closed-form expressions: one has been known previously, while the other appears to be new. Our result points toward a relatively simple landscape of possible blowup scenarios for high-dimensional Yang-Mills equations. Beyond its purely mathematical interest, this rigidity of self-similar blowup may also be relevant from a physical perspective, as it constrains the possible ultraviolet dynamics of non-abelian gauge fields in higher-dimensional Yang-Mills theories arising in string-inspired extra-dimensional setups and in holographic models.