Exact Solutions of the SU(2) Yang-Mills Equations from a Static Ansatz

Abstract

We present a systematic study of static solutions to the source-free SU(2) Yang-Mills equations, in which the gauge potential explicitly depends on spin operators. By employing the vector potential extraction approach -- which requires the total angular momentum operator (orbital plus spin) to satisfy the standard angular momentum algebra -- we derive the most general form of the spin vector potential A. This leads to the static ansatz \ A = [k1(r×Γ) + k2Γ + k3(Γ·r)r]/r, φ= f1(r)\,(Γ·r) + f2(r)\, parametrized by three constants \k1, k2, k3\ and two radial functions \f1(r), f2(r)\. After substituting this static ansatz into the Yang-Mills equations we obtain a set of consistency equations. Solving these equations provides a complete classification of the exact static solutions, including both real and complex families. The known simple SU(2) static solution \A=k (r×Γ)/r, φ=κ/r \ is recovered as a special case. Our classification reveals new static configurations that could be valuable for non-perturbative studies and for models where the internal spin couples to non-Abelian gauge fields.