Local Topological Constraints on Berry Curvature in Spin--Orbit Coupled BECs

Abstract

We establish a local topological obstruction to flattening Berry curvature in spin-orbit-coupled Bose-Einstein condensates (SOC BECs), valid even when the global Chern number vanishes. For a generic two-component SOC BEC, the extended parameter space M=T2BZ× S1ϕ+× S1ϕ- carries a Kaluza-Klein metric gM and a natural metric connection ∇C whose torsion 3-form encodes the synthetic gauge fields. Its harmonic part defines a mixed cohomology class in (H2(T2BZ) H1(S1ϕ+))(H2(T2BZ) H1(S1ϕ-)) of mixed tensor rank one. Adapting the Pigazzini-Toda lower bound to the Kaluza-Klein setting through exact pointwise curvature analysis (constant Berry curvatures), we show that the obstruction kernel vanishes and obtain a three-level non-reducibility structure for the physical metric: (i) for the one-parameter family interpolating between the product and physical metrics, holoff(∇C)1 at every point for all ∈(0,1); (ii) at the physical metric, every non-Bismut torsion representative of [ω] yields holoff1 on an open set; (iii) the horizontal-vertical splitting is not invariant under the Riemannian holonomy of the physical metric, with holoff(∇LC)1 at every point. These bounds prevent the complete gauging-away of Berry phases even at zero net topological charge. The corrected rank r detects the robustness of the constraint under phase-reduction protocols: no single phase-locking can eliminate the obstruction, a distinction invisible to the mixed rank r alone. This provides the first cohomological lower bound certifying locally irremovable curvature in SOC BECs beyond the Chern-number paradigm.