An SO(3) Gauge Theory of Turbulence with Spontaneous Symmetry Breaking

Abstract

Fully developed isotropic turbulence exhibits a dual nature: a continuous, scale-invariant energy cascade coexists with discrete, intense vortex filaments. We show that this duality arises from a spontaneously broken SO(3) gauge symmetry. By identifying the specific angular momentum L = r×u as a non-Abelian gauge connection and the radial velocity ur as a Higgs field, the turbulent vacuum is described by the SO(3) Georgi-Glashow model. When the radial strain condenses, the symmetry breaks SO(3) U(1), generating a topological mass gap MW = gv. This gap partitions the energy into a massless U(1) sector (the solenoidal background) that sustains the Kolmogorov cascade, and a massive SO(3)/U(1) sector that is confined to vortex filaments. Using high-resolution DNS data (JHTDB, Reλ≈433), we empirically verify three key predictions: (i) the energy spectra obey a strict 1:2 equipartition over the inertial range, with a sharp divergence at MW ≈ 40; (ii) the radial Higgs field extracted around isolated vortex cores follows the exact BPS monopole profile H(r)=(r/η)-η/r with η= 0.0093 domain units and the VEV v = 0.338, identifying the ubiquitous "worms" as macroscopic 't Hooft-Polyakov monopoles; (iii) the Wilson loop computed from the velocity field exhibits a clean area law WC e-σA with string tension σ= 0.303 0.009, directly confirming the confining nature of the turbulent vacuum.

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