Submitted:
01 July 2026
Posted:
01 July 2026
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Abstract
Keywords:
1. Introduction
1.1. Prior Work and the Gauge-Admissibility Problem
1.2. Main Result and Scope
- 1.
- Compactness under normalized local group averaging. A finite regulator of the bounded-domain theory replaces the local gauge group by a product of interior group factors containing . If each factor is averaged with a normalized invariant Haar probability measure, then G must be compact, since such a measure exists only for compact G [8]. This is a condition of the group-averaging prescription used here, not a universal no-go theorem for every quantization of a noncompact gauge symmetry [9].
- 2.
- Ordinary anomaly obstructions. The chiral representation content must be free of perturbative and global gauge anomalies. The window is BRST-inert, so it leaves the ordinary local BRST cohomology unchanged in the interior and cannot make the single-valued fermion determinant requirement easier to satisfy. The anomaly obstruction is not created or concentrated at ; it is already present wherever , and the boundary layer, at most, carries representative-level contact terms.
- 3.
- Global form and Gribov data. The global form of the non-Abelian gauge group, the allowed bundle and line-operator sectors, the boundary gauge group, and the Gribov/fundamental-modular-region prescription must be specified on the bounded domain. A local Faddeev–Popov slice does not fix these data. Abelian factors carry no field-dependent Gribov horizon and are exempt from the non-Abelian part of this condition once their ordinary zero modes are fixed.
1.3. Plan of the Paper
2. Windowed Gauge Theory: Inherited Assumptions and Ward Identity
2.1. Inherited Gauge-Fixed Windowed Action
2.2. Windowed Ward Identity
2.3. Boundary Layer Geometry
3. Compactness under Normalized Finite-Domain Group Averaging
3.1. The Functional Measure on a Bounded Domain
3.2. Implications for the Gauge Algebra
4. Ordinary Anomaly Obstructions and Window-Dependent Boundary Terms
4.1. Gauge Anomalies and the Windowed Identity
4.2. The Ordinary Anomaly Survives in the Interior
4.3. Boundary Transgression of Anomaly Representatives
- (i)
- wherever , the ordinary consistent anomaly is recovered exactly;
- (ii)
-
the window-weighted four-form is not, by itself, BRST closed when . Applying the BRST operator and using and Equation (23) gives, up to an outer-boundary term,with of ghost number two and supported on ;
- (iii)
- in a regular sharp-window limit , so that , any -weighted boundary term becomes a codimension-one surface term over .
4.4. Which Representations Are Anomaly-Free
- for (the series, including the accidental isomorphism ): an independent cubic adjoint invariant exists; can be nonzero for representations of complex type, and in particular it is nonzero for the fundamental , while it vanishes identically for real and pseudoreal representations. These are the only simple algebras with a nonzero pure cubic gauge anomaly [25,27].
- : no independent cubic invariant, so the perturbative cubic anomaly vanishes for every representation. Its representations are real or pseudoreal. Pseudoreal representations can still participate in the global anomaly [21], so vanishing of the perturbative cubic coefficient does not by itself imply global anomaly freedom.
- for and , and the compact symplectic algebras : no independent cubic adjoint invariant, so for every representation [26].
- The exceptional algebras : no independent cubic adjoint invariant, so for every representation, even where some representations are complex. The algebra is the instructive case: its is complex, yet the pure gauge anomaly vanishes, since the familiar cubic invariant of lives in the matter indices of , not in the adjoint indices that carry the gauge anomaly [25,27].
5. Gribov Geometry and Global Gauge Data on Bounded Domains
5.1. Euclidean Gauge-Fixed Setup
5.2. Local Gribov Geometry
5.3. Global Sector Specification
5.4. Finite-Size Spectral Estimate
6. Finite-Domain Gauge Admissibility and the Standard Model Application
6.1. Statement of Constraints
- (C1)
- Under the normalized local group-averaging prescription of Proposition 1, G is compact.
- (C2)
- The representation content is anomaly-free: the pure and mixed-gauge perturbative coefficients vanish (, with indices ranging over the full reductive algebra), the mixed gauge–gravitational coefficients vanish, and global gauge anomalies are absent, by the interior BRST test of Lemma 1 and the separate single-valuedness requirement on the fermion determinant.
- (C3)
- The global form of the non-Abelian gauge group, the allowed bundle and line-operator sectors, the boundary gauge group, and the Gribov/modular-region prescription must be specified. The simply connected cover provides a convenient reference presentation, but it is not the only admissible global form; finite central quotients are admissible when their associated global-sector data are supplied. Abelian factors carry no field-dependent Gribov horizon and are exempt from the non-Abelian part of this condition after ordinary zero modes are fixed.
6.2. Finite-Domain Gauge-Admissibility Theorem
- (A1)
- the boundary gauge redundancy is the based gauge group of Equation (8), or an explicit edge-sector replacement is supplied;
- (A2)
- the regulated local group averaging uses a normalized invariant Haar measure on each local group factor, as in Proposition 1;
- (A3)
- the gauge-fixed Euclidean operator problem uses a specified Landau-type gauge with elliptic, self-adjoint ghost boundary conditions;
- (A4)
- the renormalized effective action and its local Slavnov–Taylor breaking functional are well defined, so that the breaking can be classified by local BRST cohomology.
- (i)
- G is compact, under assumption [ass:A2](A2);
- (ii)
-
the ordinary local perturbative gauge-anomaly obstructions of the supplied chiral matter vanish. The pure and mixed-gauge cubic coefficients satisfywith as in Equation (15) and the indices ranging over the full reductive gauge algebra; the mixed gauge–gravitational coefficients vanish,and global gauge anomalies are absent;
- (iii)
- the global form, bundle sectors, line-operator content, boundary gauge group, and Gribov/modular-region prescription are specified, as in Propositions 3 and 4; Abelian factors are exempt from the non-Abelian part after ordinary zero modes are fixed.
6.3. Matter Admissibility and Absence of Window-Based Selection
- (i)
- compactness of G allows each to be chosen unitary, by averaging an invariant inner product;
- (ii)
- all perturbative gauge anomalies vanish,
- (iii)
- all mixed gauge, mixed gauge-gravitational, and global anomalies are absent.
6.4. Classification of Admissible Minimal Gauge Groups
6.5. Standard Model Anomaly Conditions
6.6. Application to Observed Quark-Lepton Matter
- (i)
- The strong-interaction factor must accommodate an irreducible three-dimensional representation of complex type, the observed color triplet. Among compact simple Lie algebras, is the unique algebra admitting a three-dimensional irreducible representation of complex type, so the complex-triplet requirement forces the color algebra to . Larger candidates are excluded by minimality: has smallest complex-type representation the , so hosting the observed quarks there would require enlarged color multiplets or additional matter. The algebra has no three-dimensional irreducible representation of complex type, and has no three-dimensional irreducible representation at all, since all its irreducibles are one-dimensional.
- (ii)
- The weak-interaction factor must contain an irreducible two-state representation accommodating the left-handed doublets with nontrivial chiral structure. Among compact connected non-Abelian simple groups admitting a nontrivial irreducible two-dimensional representation, the local Lie algebra is uniquely , whose fundamental is the pseudoreal doublet . Minimality therefore selects as the reference covering factor.
- (iii)
- After is specified, the perturbative anomaly conditions of Equations (37)–(40) fix the hypercharge assignments up to the branch selection of Section 6.5, with the SM branch chosen by the nontrivial chiral assignment and up/down identification. A single factor is both necessary, to assign distinct hypercharges to quarks and leptons, and sufficient.
6.7. Standard Model Global Form
6.8. Scalar-Sector Compatibility and the Minimal Higgs Doublet
7. Discussion
7.1. What Is Established Conditionally
7.2. What Remains Ordinary Gauge Theory
7.3. What the Standard Model Application Assumes
7.4. What the Paper Does Not Establish
7.5. Limitations and Calculations Deferred to Subsequent Work
8. Conclusions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
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