Study of the Laplace–Beltrami operator on sections of the orientation line bundle over a constant-curvature Möbius band with a cone-point defect, comparing the Friedrichs extension and the sector-regular bridging (renormalized 2D point interaction) family. The cone interaction fixes an extension-dependent ground state (Friedrichs has a discontinuous zero mode; bridging produces a logarithmic negative bound state), while the first positive eigenvalue is stable across these realizations and admits explicit closed-form values with a width-driven mode crossing.
The submission is internally coherent overall. The boundary conditions, sector parities, seam anti-periodicity/periodicity, and distinction between Friedrichs and sector-regular bridging extensions are used consistently. The parity dictionary in Section 4.1 follows logically from the earlier anti-equivariant seam condition in Section 3.4, and the later mode-crossing theorem uses the same sector labels and cone conditions. The stated scope restriction in Remark 1.3 is important and is respected later: Theorem 1.2 is not overclaimed for arbitrary self-adjoint extensions in the wide-band limit-circle odd sector. Minor consistency issues remain. In Lemma 4.1 and nearby text, the Friedrichs form is sometimes described as decomposing into two half-band forms, while elsewhere the regular seam identification still couples the two halves through anti-periodicity. The actual calculations retain the seam condition, so this is a wording/structural ambiguity rather than a contradiction. There is also a mild normalization ambiguity in the reduced cone boundary form, where transverse integration factors are suppressed; because this only rescales the boundary symplectic form and not the Lagrangian extension planes, it does not undermine the main conclusions.
Mathematical Validity4/5
high confidence- spread 1- panel
The mathematical structure is sound and the main derivations are mostly reproducible. The Laplace-Beltrami reduction with weight |cos(y/R)|, the indicial equation s^2 = μR^2, and the limit-point/limit-circle classifications are consistent. The constant-sector Legendre reduction in Section 4 is correct in form: x = sin(y/R) gives the Legendre equation with λ = ν(ν+1)/R^2; the symmetric tower Pν(0)=0 gives odd ν, and the Friedrichs antisymmetric tower Pν'(0)=0 gives even ν. The secular function G(λ) is derived using standard DLMF values for Pν'(0), Qν'(0), and the logarithmic asymptotic of Qν, and the threshold G(2/R^2) = -1 correctly yields δ0 = 2R/e. The nonconstant sector eigenfunctions |cos(y/R)|^α times the transverse modes also check dimensionally and satisfy the stated seam conditions, with eigenvalue α(α+1)/R^2. The main reason this is not a 5 is that several functional-analytic steps are compressed rather than fully formalized: the exact unfolding from Neumann interval link to the cited BP circle-link cone traces, the full direct-sum self-adjointness/compact-resolvent proof, and the global lune equivalence through the singular vertices. These gaps are mostly standard and not fatal, but a rigorous publication-level proof would need to expand them. I did not find a central equation that is dimensionally inconsistent or a central theorem whose proof is circular.
Falsifiability3/5
high confidence- spread 0- panel
The work makes clear quantitative predictions, but primarily for an idealized mathematical model rather than for a specified physical system. On the positive side, the predictions are sharp: exact formulas for λ1(W), a critical width W=πR/2 for mode crossing, a defect-bound state asymptotic λb(δ0), and a threshold δ0=2R/e separating spectral orderings. These are the kinds of statements that could be falsified by spectroscopy in an engineered analogue realizing the same operator domain and geometry. The paper also distinguishes which observables are extension-dependent and which are robust across the Friedrichs and bridging realizations, which strengthens discriminability.
What limits the score is that the manuscript does not provide an experimental protocol, identify a concrete platform where the orientation-line-bundle twist and sector-regular bridging extension can both be implemented, or state explicit observational signatures in laboratory units. There is no direct discussion of what measurement would rule out the proposed bridging family versus Friedrichs in practice, beyond the model-level statement that one has a negative bound state and the other a zero mode. So the paper is definitely falsifiable in principle and quantitatively so, but not yet translated into a near-term empirical test program.
Clarity3/5
high confidence- spread 0- panel
The paper is overall well organized, with a strong high-level roadmap, clear sectioning, and repeated summaries of what each extension or sector does. A graduate-level mathematical physics reader can follow the main storyline: geometry → sector decomposition → extension choice → zonal analysis → nonconstant sectors → physical interpretation. The introduction and theorem statements are especially effective at communicating the central claims.
However, clarity is held back by the density of the exposition and by notation/terminology load. The manuscript is technically verbose, often introducing several geometric pictures and operator-theoretic distinctions in a single passage. Readers outside spectral geometry may struggle with the rapid alternation between Möbius-band, double-lune, cone-trace, and parity-reduced viewpoints. In addition, the symbol ψ is reused for both the section/wavefunction and the digamma function in §4.4, even though this is flagged; under the rubric, that redefinition prevents a higher score. So the work is intelligible and mostly consistent, but not exceptionally transparent.
Novelty4/5
high confidence- spread 0- panel
This is a genuinely original synthesis of several known ingredients: twisted quantum mechanics on a non-orientable manifold, a conic singularity, self-adjoint extension theory at the apex, and explicit solvability via Legendre reduction. The key novel scientific contribution is not merely 'another cone Laplacian calculation,' but the separation of roles between global holonomy and local defect extension: the claim that the defect controls the ground state while topology/curvature control a stable first positive level across a nontrivial family of extensions. That separation, together with the explicit width-driven crossing and the comparison between Friedrichs and sector-regular bridging realizations on a Möbius geometry, appears nontrivial and meaningfully new.
The author also shows awareness of prior work and positions the contribution carefully relative to AGHH, Kay-Studer, Boscain-Prandi, and Möbius-strip literature. I do not rate it a 5 because the paper is constructed from established mathematical machinery rather than introducing an entirely new foundational mechanism or formalism; its novelty lies in the assembly, exact solution, and interpretive separation of effects rather than in a brand-new theoretical structure.
Completeness4/5
high confidence- spread 1- panel
The submission is substantially complete within its stated scope. It defines the geometric model, specifies the operator and Hilbert space, makes the seam and boundary conditions explicit, identifies where self-adjoint extension freedom lives, states the sector-regular restriction clearly, and addresses the narrow/wide width regimes separately. The main edge cases are discussed: the critical width W = pi R/2, the wide-band first odd limit-circle sector, the threshold delta_0 = 2R/e, the behavior as delta_0 -> 0 and infinity, and the distinction between first positive eigenvalue and spectral gap.
Its limitations are also reasonably explicit. In particular, the author repeatedly narrows the claim to the Friedrichs and sector-regular bridging families rather than all self-adjoint extensions, and remarks that non-sector-regular odd-branch extensions in the wide-band regime are outside scope. This is good completeness practice because it prevents overclaiming.
The main reason the score is 4 rather than 5 is that several support points are present but somewhat compressed relative to the paper's technical ambition. The dependence on cited extension-theory results is appropriate, but a few operational details would benefit from fuller closure: for example, the claim that the bridging realization is the curved-cone analogue of the standard renormalized 2D point interaction is motivated well but not developed into a fully self-contained identification; the statement that the first positive eigenvalue is simple away from critical width is plausible from the sector analysis but not separately justified in much detail; and the handling of general parity-mixing Lagrangian conditions is acknowledged but only partially contextualized. None of these appears to break the core argument, but they leave some secondary completeness gaps.
Publication criteria: All dimensions must score at least 2/5 with an overall average of 3/5 or higher. The AI recommendation badge above is advisory - publication is determined by the numerical scores.
These are equations, theorem steps, or proof moves where math specialists identified compressed or unverified derivations. They are shown once here as the canonical deduplicated list so the review stays auditable without repeating the same flags in every math specialist report.
high
Section 4.4: closed form for secular function G(λ) and eigenvalue condition G(λ)=ln(δ0/2R) - Load-bearing derivation is incomplete: mapping from Neumann-normalized half-interval solution u_λ to Legendre combination a P_ν(x)+ b Q_ν(x), extraction of (𝒩(λ),𝒟(λ)) from Q-asymptotics near x→1, and the identification G = -𝒟/𝒩 = -γ-ψ(ν+1) - Q′_ν(0)/P′_ν(0). The DLMF expansions/derivatives are cited, but the intermediate algebra connecting boundary conditions at y=0 to the ratio Q′(0)/P′(0) is not fully shown.
If wrong: If G(λ) is miscomputed, then Proposition 4.4 (existence/uniqueness and monotonicity of the negative bound state, exclusion of zero, interlacing, and the δ0 threshold 2R/e) could be wrong. This would directly undermine Theorem 1.1(iii) and the δ0>2R/e stability range in Theorem 1.2.
medium
Lemma 3.1 (Neumann unfolding) / identification with BP cone model α_BP=-1 - The unitary identification between Neumann interval modes and circle-link Fourier modes is described conceptually but not constructed explicitly with norms and domain correspondence; the claim that ‘maximal domain, Lagrange bracket, deficiency indices depend only on local behavior’ is correct in spirit, but the precise mapping to BP’s parameter α_BP=-1 and the two-sided cone trace space would benefit from an explicit local coordinate/model-operator equivalence proof.
If wrong: If the local model equivalence or trace-coordinate identification is off, the stated deficiency indices (Lemma 3.3) and the specific form of cone boundary pairing (Section 3.5) could change, affecting which sectors are extension-ambiguous and thus the classification of realizations used in Theorems 1.1–1.2.
medium
Lemma 3.1 and Section 3.5 cone trace normalization - The Neumann unfolding to a circle-link cone and the resulting cone boundary trace form are sketched rather than fully derived, especially the normalization of the boundary form after transverse integration. The omitted transverse factor is likely harmless because it rescales the symplectic form and does not change the Lagrangian extension conditions, but the normalization is load-bearing for matching the δ0 convention to the point-interaction scale.
If wrong: If the unfolding or normalization were incompatible with the BP cone model, the exact identification of the Friedrichs and bridging trace conditions, and hence the δ0-dependent secular equation, would require correction. The qualitative extension dichotomy would likely survive, but the numerical threshold δ0 = 2R/e or the bound-state scale could shift.
medium
Lemma 4.3 monotonicity proof - The monotonicity of $G$ is proved by a Green identity calculation that is compressed: the cancellation of cone boundary terms and the normalization are described but not written out in full step-by-step detail. A reader must supply the intermediate algebra.
If wrong: If the monotonicity argument fails, the uniqueness and interlacing statements for the bridging eigenvalues (Proposition 4.4) would be unsupported, weakening the classification of the first positive level across the bridging family. The central Theorem 1.1(iii) bound-state existence is unaffected (it follows from the asymptotic alone), but the strict monotonicity and gap-interlacing structure would be unreliable.
medium
Proposition 4.2 lune equivalence - The unitary equivalence between the Friedrichs twisted problem and the Neumann spherical lune is plausible and substantially argued, but the global geometric identification and the mapping of the Friedrichs form domain through the singular vertices are presented in a compressed way. The zero-capacity cutoff argument is given, but a fully formal proof would need to specify the quotient/lune charts and trace behavior at the identified vertices more carefully.
If wrong: If the lune equivalence failed, the interpretive statement that the Friedrichs spectrum is exactly the Neumann lune spectrum would be unreliable. However, the main first-positive eigenvalue formula is also derived directly by the sector/Legendre analysis, so Theorem 1.2 would not necessarily fail.
medium
Proposition 6.1 / sector ground-state transform argument for λ=α(α+1)/R^2 - The explicit verification that u=|cos(y/R)|^α solves the reduced Sturm–Liouville equation is provided, but the subsequent claim that this eigenvalue is the sector ground eigenvalue uses a ground-state transform/oscillation argument in prose without fully stating domain issues at the cone (especially in the wide-band odd sector where 0<α<1 and the endpoint is limit-circle).
If wrong: If λ=α(α+1)/R^2 were not actually the lowest eigenvalue for that sector under the chosen (regular) cone condition, then the mode-crossing and the explicit piecewise formula for λ1(W) in Theorem 1.2 could fail.
low
Lemma 4.1 cutoff estimate placing discontinuous φ0 in the Friedrichs form domain - The logarithmic cutoff construction is standard (capacity-zero point in 2D), but the paper compresses the argument; in particular the bound on χ′_ε and the translation from the 1D δ-estimate to the full 2D form norm is only briefly indicated.
If wrong: If φ0 were not in the Friedrichs form domain, then inf σ(Δ_F)=0 attained by φ0 would be unsupported and the ‘universal bound infσ(A)≤0’ argument relying on λ0(Δ_F)=0 would weaken.
low
Proposition 3.7 - The proof that the sectorwise direct sum is self-adjoint with compact resolvent is compressed and partly refers forward to the sector-bottom divergence established in Section 6.2. This is standard for orthogonal sums of compact-resolvent sector operators with sector bottoms tending to infinity, but the domain of the full operator and the summability conditions are not written out in full.
If wrong: If the direct-sum compactness statement failed, the paper's enumeration of discrete eigenvalues would need qualification. The explicit sector eigenvalue computations would remain meaningful, but the global spectral ordering used in Theorem 1.2 would be less rigorously justified.
low
Proposition 3.7 (direct sum self-adjointness/compact resolvent for the sector sum) - The claim that the orthogonal direct sum of sector operators has compact resolvent is asserted using ‘sector bottoms diverge’ with a reference to an end-of-§6.2 argument. The functional-analytic justification (e.g., compactness of resolvent of direct sum iff eigenvalues →∞ suitably) is standard but not spelled out.
If wrong: If compact resolvent failed, discreteness and ‘first positive eigenvalue = min of sector bottoms’ could fail. However on a finite interval with separated boundary conditions per sector this is very likely correct.
low
Proposition 4.4 derivation of G(ν(ν+1)/R^2) - The closed form of $G(ν(ν+1)/R^2)$ involves the ratio $Q_ν'(0)/P_ν'(0)$ and uses the identity $P_ν'(0) Q_ν'(0) = π/2 · [ψ(ν/2+...) ...]$ (or equivalent). The quoted DLMF formulas are provided, but the cancellation step yielding $π/2 π(πν/2)$ is only noted as “Gamma quotient cancels.” It’s plausible but not fully shown.
If wrong: Peripheral: the exact form of $G$ is used to locate the threshold $δ_0 = 2R/e$; a minor error would shift this constant but not change the qualitative stability region ($δ_0$ large enough) nor the main Theorem 1.2 mode-crossing result.
low
Proposition 6.2 even nonconstant sector ground state - The claim that the sign-flipped solution sgn(δ)|cos(y/R)|^α is the sector ground state is justified by a short Sturm oscillation argument on half-intervals. This is plausible, but the paper does not fully spell out the matching between the two half-interval ground states and the anti-periodic seam condition in the global sector domain.
If wrong: If this ground-state identification failed, the proof that all even nonconstant sectors lie above 2/R^2 would need another argument. The first-positive-level theorem would be affected only if an even nonconstant sector could drop below the stated branches, which appears unlikely given α_k > 1 and the displayed eigenvalue.
low
Section 3.5: boundary form [u,v]_{pc} = (1/R) Σ± (u_D^± v_N^± - u_N^± v_D^±) - The derivation of the precise prefactor 1/R and sign conventions from the two-sided Green identity is sketched via asymptotics. Given the absolute value in the weight |f| and the two-sided orientation, this is plausible but not fully written out.
If wrong: A wrong overall prefactor would not affect Lagrangian-plane classification (symplectic form scaling), but a wrong relative sign between sides could alter the ‘Kirchhoff’ flux matching condition and hence the self-adjointness of the proposed bridging plane.
low
Section 4.4: Legendre function of the second kind normalization - The identification of the constant $2R$ in the expansion of $Q_ν(ν(y/R))$ relies on the formula $(1-x)/2 = δ^2/(2R^2) + ...$ and the DLMF expansion. The matching to the cone trace coordinates is stated but the full $O(δ^2)$ verification is omitted.
If wrong: Local normalization: would shift the reference length in $G$ but not affect eigenvalues or spectral structure.
low
Theorem 5.1 proof, shifted-extension comment - The main proof of the universal bound uses the correct nonnegative-extension argument, but the additional sentence saying that after shifting any semibounded extension the BKV order 'covers them all' is terse and potentially imprecise unless one also shifts the minimal operator and its Friedrichs extension. This is not needed for the theorem as stated.
If wrong: If read literally, this shifted-extension shortcut could misstate the BKV comparison for non-nonnegative extensions. The theorem's conclusion still follows from the separate cases: nonnegative extensions are bounded by Friedrichs, and non-nonnegative extensions have negative spectral bottom.
This paper presents a rigorous and original spectral analysis of the Laplace–Beltrami operator on sections of the orientation line bundle over a conic Möbius band, demonstrating a clean separation between two spectral mechanisms: the cone defect controls the ground state, while the topological holonomy and curvature control the first positive eigenvalue. The panel awarded strong scores across internal consistency (4/5), mathematical validity (4/5), novelty (4/5), and completeness (4/5), with moderate scores for falsifiability (3/5) and clarity (3/5).
The mathematical structure is generally sound. The transverse decomposition into Neumann sectors, the limit-point/limit-circle classification via the indicial equation s²=μR², the Friedrichs maximality argument via the Birman–Krein–Vishik order (Lemma 3.8), and the explicit Legendre reduction of the constant sector are all correct and consistently applied. The symmetric zonal tower Pν(0)=0 giving odd ν and eigenvalue 2/R² (Section 4.2) is cleanly derived. The mode-crossing formula λ₁(W) with critical width W=πR/2 follows logically from the sector-bottom comparison. However, one load-bearing derivation requires attention: the secular function G(λ) in Section 4.4, central to Proposition 4.4 and Theorem 1.1(iii), is not derived with sufficient intermediate steps. Specifically, the mapping from the Neumann-normalized half-interval solution uλ to the Legendre combination aPν+bQν, the extraction of (𝒩(λ),𝒟(λ)) from Qν asymptotics near x→1, and the cancellation of Gamma factors yielding G = −γ−ψ(ν+1)−(π/2)cot(πν/2) are asserted with references to DLMF formulas but without the intermediate algebra. This step drives the bound-state existence, the exclusion of zero from the bridging spectrum, the interlacing structure, and the exact threshold δ₀=2R/e. Two specialists flagged this as a HIGH risk item. Similarly, the monotonicity proof of G in Lemma 4.3 is presented in compressed form—the Green identity cancellation of cone boundary terms is described but not written out—which is a MEDIUM risk item affecting the uniqueness and interlacing claims of Proposition 4.4. The Neumann unfolding identification with the BP circle-link cone model (Lemma 3.1) and the corresponding cone trace normalization in Section 3.5 are also sketched at a level that leaves open whether the exact δ₀ convention and boundary symplectic form prefactor 1/R are correctly matched (MEDIUM risk). Additional compressed steps include the compact-resolvent argument for the direct-sum operator in Proposition 3.7 (LOW risk, standard but not written out), the Friedrichs form-domain placement of φ₀ via the logarithmic cutoff in Lemma 4.1 (LOW risk, standard capacity argument), and the ground-state transform in the wide-band first odd sector in Section 6.1 (MEDIUM risk, domain and integration-by-parts at the limit-circle endpoint not fully formalized). These do not constitute decisive failures—two specialists found no central contradiction or invalid conclusion—but they represent points where a fully rigorous publication-ready version would need expansion.
On novelty, the panel assessed the contribution as genuinely original (4/5). The paper does not introduce a new extension theory or formalism, and appropriately disclaims this, but the exact assembly of orientation-bundle holonomy, conic defect, and constant-curvature exact solvability in a non-orientable geometry is new. The identification of the Friedrichs realization with a Neumann spherical lune (Proposition 4.2) and its explicit failure for every bridging extension is an elegant and non-obvious result. The width-driven crossing at W=πR/2 with the sharp threshold δ₀=2R/e is a concrete and checkable prediction. The comparison with Kalvoda–Krejčiřík–Zahradová [KKZ] is careful and honest: the two models differ in whether the twist is carried geometrically or as a bundle holonomy, producing different thin-strip limits (zonal Legendre vs. Mathieu). Completeness is likewise strong (4/5): all boundary conditions, sector parities, and edge cases at critical parameters are addressed, with explicit scope restrictions appropriately stated in Remark 1.3 and Definition 3.5.
Falsifiability and clarity are the areas most in need of development. The predictions are mathematically sharp—exact eigenvalue formulas, an explicit bound-state asymptotic with the universal 2D point-interaction constant −4e^{−2γ}/δ₀², and a critical width—but the paper does not identify a concrete experimental platform where the orientation-line-bundle twist and sector-regular bridging extension could both be realized, nor does it state what measurement would distinguish Friedrichs from bridging in practice. The renormalization length δ₀ is acknowledged as a free extension parameter not fixed by geometry, which limits predictive contact with experiment. For clarity, the specialist panel's mandatory observation is that ψ is overloaded as both the bundle section/wavefunction and the digamma function in Section 4.4 (flagged in the text but still present), which caps the clarity score. The prose is technically dense, with rapid alternation between the Möbius-band, double-lune, cone-trace, and parity-reduced viewpoints that may be challenging for readers outside spectral geometry. Additionally, external figure hosting (GitHub URLs) means that if those links are unavailable, geometric intuition and branch-structure support would be lost.
This work departs from mainstream consensus physics in the following ways. These are not penalties - they are informational flags that highlight where the author proposes alternative interpretations of physical phenomena. The scores above evaluate rigor, not orthodoxy.
◈The paper studies quantum mechanics on a non-orientable manifold (Möbius band) with a conic metric singularity, which lies outside the standard smooth compact Riemannian setting assumed in most spectral geometry; this is a well-developed but non-mainstream geometric setting and not a departure from consensus physics per se.
◈The paper takes the orientation line bundle holonomy as the physical Hilbert space rather than scalar wavefunctions, treating the sign-reversal around the core loop as a physical boundary condition analogous to an Aharonov–Bohm phase; this is mathematically standard for line bundles but is a non-default choice of quantum mechanical configuration space.
◈The paper demonstrates that no self-adjoint extension of the twisted Laplacian on M(W) has strictly positive spectral bottom, meaning the standard Perron–Frobenius mechanism for a positive ground state is unavailable; this is a mathematical result within the model and not a departure from consensus physics, but it may be counterintuitive to readers expecting a positive ground state from elliptic operators.
◈The renormalization length δ₀ entering the bridging realization is treated as a free extension parameter not determined by intrinsic geometry, in contrast to settings where smoothed-cone limits select a canonical extension; the paper correctly flags this as an open question rather than a resolved choice.
Strengths
Clean logical separation of two spectral mechanisms: the Möbius orientation-bundle holonomy and the conic defect extension are shown to act on disjoint spectral data, with the defect controlling the ground state and topology/curvature controlling the first positive level, a nontrivial and well-supported organizing idea.
Exact closed-form eigenvalues and eigenfunctions via Legendre reduction throughout, including the symmetric zonal tower, the width-dependent odd-sector ground state, and the secular function G(λ) for the bridging family, making all central claims independently checkable.
Rigorous Friedrichs maximality via Birman–Krein–Vishik order (Lemma 3.8) giving the universal bound infσ(A)≤0 for every self-adjoint extension without parity hypotheses, clearly separating the universal part of Theorem 1.1 from the extension-specific parts.
The unitary equivalence of the Friedrichs realization with the Neumann spherical lune (Proposition 4.2) is an elegant result, with the zero-capacity cutoff argument for the cone point well executed, and its explicit failure for every bridging extension is nontrivially established via spectral invariants.
Careful scope discipline: sector-regularity is precisely defined (Definition 3.5), the wide-band (4,4)-deficiency case is handled separately (Lemma 3.3), and Remark 1.3 explicitly delimits Theorem 1.2 to avoid overclaiming for non-sector-regular extensions.
Thorough treatment of edge cases: critical width W=πR/2 producing double degeneracy, threshold δ₀=2R/e producing triple degeneracy (Corollary 6.3), thin-strip and smooth-comparison limiting regimes addressed in §7 with explicit contrast to [KKZ].
Areas for Improvement
Expand Section 4.4 to provide the missing intermediate derivation of G(λ): explicitly show the mapping from the Neumann-normalized solution uλ to the Legendre combination aPν+bQν, extract (𝒩(λ),𝒟(λ)) from the Qν asymptotic near x→1, and demonstrate the Gamma-factor cancellation yielding G = −γ−ψ(ν+1)−(π/2)cot(πν/2). This is the highest-risk derivation gap in the paper and the main obstacle to a higher mathematical validity score.
Provide a fuller derivation of G monotonicity in Lemma 4.3: write out the Green identity cone-boundary-term cancellation step by step rather than describing it in prose, making the uniqueness and interlacing claims of Proposition 4.4 fully self-contained.
Clarify the Neumann unfolding and cone trace normalization in Lemma 3.1 and Section 3.5: give an explicit local coordinate/model-operator equivalence to the BP circle-link cone at α_BP=−1, making the trace space dimension, boundary form prefactor 1/R, and the δ₀ convention rigorously derived rather than imported by analogy.
Formalize the ground-state transform integration-by-parts argument in Section 6.1 for the wide-band first odd sector (0<α₀<1, limit-circle endpoint): state the self-adjoint boundary condition imposed and verify the boundary term vanishing for domain elements in the chosen (regular Frobenius) extension before asserting λ=α₀(α₀+1)/R^2 is the sector ground eigenvalue.
Replace the symbol overloading of ψ (bundle section and digamma function in Section 4.4): use a distinct symbol such as Ψ or ψ_d for the digamma function throughout, which is currently flagged and caps the clarity score.
Add a brief experimental-contact discussion: identify at least one candidate mesoscopic or photonic platform (e.g., Möbius-ring or topological metamaterial) where the orientation-bundle twist and a tunable short-distance parameter could be engineered, and state what spectroscopic measurement would distinguish Friedrichs from bridging realizations, even qualitatively.
Host the figures (currently at external GitHub URLs) in a more stable or self-contained format, or include them inline, to ensure the double-lune schematic and mode-crossing plots remain accessible without external link resolution.
Expand Proposition 3.7 to include the explicit functional-analytic lemma for compact resolvent of the direct sum, rather than forward-referencing Section 6.2 for the sector-bottom divergence needed to complete the argument.
1 model failed to respondReduced Panel (8/9)
anthropic/claude-opus-4-7(math)
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Key Equations (3)
G(λ)=ln2Rδ0
Secular equation for bridging realizations: G(λ) is the ratio -D(λ)/N(λ) computed from Legendre data; roots give bridging eigenvalues at renormalization length δ_0.
λb(δ0)=−δ024e−2γ(1+O(δ02/R2))(δ0→0+)
Small-δ_0 asymptotic of the unique negative bound-state (defect-localized) eigenvalue in the bridging realization; γ is the Euler–Mascheroni constant.
Piecewise closed-form expression for the first positive eigenvalue λ1(W) shared by the Friedrichs extension and by sector-regular bridging with δ_0>2R/e; the two branches cross at W=πR/2.
Other Equations (6)
s2=μR2
Indicial equation near the cone point (δ = y - πR/2) determining local exponents s for the regular-singular endpoint.
ds2=dy2+cos2(Ry)dw2
Metric on the constant-curvature spherical band used to construct the Möbius band M(W); curvature radius R and half-width W.
G(R2ν(ν+1))=−γ−ψ(ν+1)−2πcot2πν
Closed-form expression for the secular function G evaluated at λ = ν(ν+1)/R^2 in terms of the Euler constant γ, the digamma ψ, and a cotangent term whose poles are the Friedrichs antisymmetric tower.
u(δ)=uNln2R∣δ∣+uD+o(1)(δ→0)
Local two-parameter asymptotic expansion in the constant (zonal) sector near the cone: u_N is the logarithmic flux datum and u_D the regularized value.
Δψ=ψyy−R1tan(Ry)ψy+cos2(y/R)1ψww
Laplace–Beltrami operator (formal expression) acting on sections of the orientation line bundle on the smooth locus of M(W).
−(∣f∣u′)′+∣f∣μu=λ∣f∣u,f(y)=cos(y/R)
Reduced Sturm–Liouville equation for longitudinal profile u(y) in a transverse sector with transverse eigenvalue μ; |f|=|cos(y/R)| is the weight.
Testable Predictions (3)
For the Friedrichs realization and for sector-regular bridging realizations with renormalization length δ_0 > 2R/e, the first positive eigenvalue equals λ1(W) given by λ1 = 2/R^2 for 0 < W ≤ πR/2 and λ1 = α0(α0+1)/R^2 with α0 = πR/(2W) for πR/2 < W < πR, with a double degeneracy at W = πR/2.
quantumpending
Falsifiable if: Computation (numerical or analytical) of the low-lying spectrum for the specified realizations and parameters that produces a first positive eigenvalue different from the piecewise values above or demonstrates a different degeneracy at W = πR/2 for δ_0 > 2R/e.
Each sector-regular bridging realization A^{br}_{δ0} carries exactly one negative cone-localized bound state λ_b(δ0), which for small δ_0 has asymptotic scaling λ_b(δ0) ∼ −4 e^{-2γ}/δ_0^2 (up to O(δ_0^2/R^2) corrections).
quantumpending
Falsifiable if: Finding no negative eigenvalue in the bridging realization for some δ_0, or demonstrating that the negative eigenvalue does not scale as δ_0^{-2} with coefficient −4 e^{-2γ} in the small-δ_0 regime (beyond numerical rounding), would falsify the claim.
No self-adjoint extension at the cone of the twisted Laplacian on M(W) has strictly positive spectral bottom; every extension satisfies inf σ(A) ≤ 0, and the Friedrichs extension attains inf σ(Δ_F)=0.
mathpending
Falsifiable if: Constructing (analytically or numerically) a self-adjoint extension of the minimal operator on M(W) whose spectrum has strictly positive infimum would contradict this claim.
Tags & Keywords
conic singularities(math)exact solvability / separation of variables(methodology)mesoscopic Möbius systems(domain)point interaction renormalization(methodology)quantum mechanics on curved surfaces(physics)self-adjoint extensions(math)spectral geometry(math)
Twisted quantum modes on a conic Möbius band: bound states, holonomy, and a stable first positive level
In a singular quantum system a global topological holonomy and a local point defect can both enter the spectrum; here they separate, the defect controlling the ground state while the topology and the curvature control the first positive level. We study an exactly solvable quantum Hamiltonian on a singular non-orientable surface: the Laplace-Beltrami operator on sections of the orientation line bundle over a constant-curvature Möbius band M(W) of curvature radius R, with one transverse fiber collapsed to a cone point. The orientation bundle imposes a Z2 sign holonomy; the collapsed fiber is a conic point defect at which the Hamiltonian is not essentially self-adjoint, whose self-adjoint extensions are the physical boundary conditions. We compare the Friedrichs realization with the sector-regular bridging family, the two-dimensional point interaction at the defect with renormalization length δ0. The ground state is extension-dependent: the Friedrichs realization has bottom 0, with a discontinuous zero mode, and is unitarily equivalent to a Neumann lune problem, while bridging carries a cone-localized defect bound state λb(δ0)=−4e−2γ/δ02(1+O(δ02/R2)) as δ0→0+, and no self-adjoint extension has strictly positive bottom. The first positive level, by contrast, is stable even though the gap above the ground state is not: for the Friedrichs extension and for bridging with δ0>2R/e it equals 2/R2 for 0<W≤πR/2 and α0(α0+1)/R2, α0=πR/(2W), beyond, a width-driven mode crossing. The spectrum is reduced explicitly to Legendre functions.
1. Introduction
Quantum mechanics on Möbius and other non-orientable geometries is by now an active mesoscopic subject, from energy levels and optical transitions on Möbius rings [LiRM] to electronic states in Möbius quantum wires [PSA]. Across it, and across the broader study of singular quantum systems, two ingredients recur: a global flat holonomy, the spectral analogue of an Aharonov-Bohm phase [Shigekawa], and a local point interaction at a defect [AGHH, KayStuder]. In many models the two spectral effects are coupled. The purpose of the present paper is to isolate them in an exactly solvable non-orientable conic geometry: the defect controls the bottom of the spectrum, while the holonomy and curvature control the first positive level.
On a Möbius band the orientation line bundle has nontrivial holonomy: after one circuit of the core loop a section changes sign. On a smooth non-orientable surface a continuous nowhere-vanishing section of the orientation line bundle would trivialize it, so the usual scalar Perron-Frobenius ground-state mechanism is unavailable for the twisted Laplacian (cf. [Shigekawa] for the magnetic spectral-positivity criterion). This paper asks how that topological obstruction is expressed when the configuration space also carries a conic defect.
The model. We study the Hamiltonian of a quantum particle constrained to a singular non-orientable surface. The operator is H=−ΔL, the Laplace-Beltrami operator on sections of the orientation line bundle L over the constant-curvature Möbius band M(W). The band is constructed from a spherical band on S2(R) of half-width W, with metric ds2=dy2+cos2(y/R)dw2, cone point pc at y=πR/2, and Neumann conditions on the regular boundary arcs. Both singular structures are intrinsic. The twist is the holonomy of the orientation bundle. The cone is produced by the metric itself, as the meridians focus at the pole of the covering sphere. The physical dictionary is short. The Möbius twist is the nontrivial flat real line-bundle holonomy, the real analogue of an Aharonov-Bohm phase π. The cone is a point defect at which H fails to be essentially self-adjoint, so the self-adjoint extensions are the physical boundary conditions at the defect. The bridging family among them realizes the standard two-dimensional point interaction, with the renormalization length δ0 entering as short-distance defect data rather than as geometry. Negative eigenvalues are defect-bound states. The paper tracks the first positive level, measured from zero rather than from the extension-dependent ground state. Constant curvature is chosen not as a geometric restriction but as an exact-solvability mechanism: every reduced one-dimensional problem below is Legendre. The competition between bundle topology and defect data therefore closes in special functions, from the operator domain to the individual eigenfunctions.
The two realizations. At pc the operator is not essentially self-adjoint in the constant transverse sector (the transverse-mode subspaces of §3.4), and it is there that the realizations we compare differ. They are the Friedrichs extensionΔF, the standard conic choice, and the sector-regular bridging realizationAδ0br, the point interaction at renormalization length δ0 (Definition 3.5). In the wide-band regime W>πR/2 the first odd transverse sector is also limit-circle at the cone. Both realizations fix it by the regular Frobenius branch, and the scope of the stability statement is fixed accordingly (Remark 1.3). Geometrically, M(W) is a spherical lune with its two vertices identified, the antipodal quotient of a double lune (Remark 2.1). The Friedrichs conditions impose independent data at the two vertices, while the bridging conditions couple them across the identification.
Results. The two singular structures act on different spectral data, and separating their effects is the point of the paper. The twist is a sign condition on eigenfunctions, while the location of the bottom is settled by the extension at the defect. The discontinuous piecewise-constant section ϕ0 is a genuine zero mode of the Friedrichs realization, whose maximality bounds the bottom of every self-adjoint extension from above by 0; the bridging family replaces ϕ0 by a logarithmic defect-bound state below zero. The gap above the ground state is therefore extension-dependent, moving with δ0, while the first positive level is stable. It is common to the Friedrichs realization and to every sector-regular bridging realization with δ0>2R/e, with a width-driven mode crossing at the critical width W=πR/2. In short, the conic defect controls the ground state, while the topology and the curvature control the first positive level.
Theorem 1.1 (Ground-state dependence on the cone interaction). Let 0<W<πR.
(i)(Universal bound) Every self-adjoint extension A at the cone of the twisted Laplacian on M(W) satisfies infσ(A)≤0, with equality if and only if A is nonnegative. In particular no self-adjoint extension has strictly positive spectral bottom.
(ii)(Friedrichs) Among the nonnegative extensions the Friedrichs extension is maximal, and its bottom 0 is attained by the discontinuous piecewise-constant zero mode ϕ0, the constant-sector kernel.
(iii)(Sector-regular bridging) The sector-regular bridging realization Aδ0br (Definition 3.5) is not nonnegative: it carries a single cone-localized negative eigenvalue λb(δ0), with small-δ0 asymptotic λb(δ0)=−4e−2γ/δ02(1+O(δ02/R2)), γ the Euler-Mascheroni constant, and zero lies in its resolvent set.
Theorem 1.2 (Stable first positive level and width-driven mode crossing). The first positive eigenvalue of the twisted Laplacian on M(W) is shared by the Friedrichs extension ΔF and by the sector-regular bridging realization Aδ0br (Definition 3.5) for every δ0>2R/e, and equals
At W=πR/2 it is doubly degenerate. Both branches are realized by explicit eigenfunctions: in the narrow regime sin(y/R), the ℓ=1 zonal Legendre polynomial; in the wide regime ∣cos(y/R)∣α0sin(πw/2W), whose profile in y is (1−x2)α0/2 in the variable x=sin(y/R), reducing to the sectoral harmonic Pα0α0 at integer degree.
Remark 1.3 (Scope of the stability statement). Theorem 1.2 is not a statement about every self-adjoint extension of the singular operator: it concerns the Friedrichs extension and the sector-regular bridging family of Definition 3.5. In the wide-band regime W>πR/2 the first odd transverse sector is also limit-circle at the cone (Lemma 3.3), and non-sector-regular extensions there lie outside the class studied here. Part (i) of Theorem 1.1 is, by contrast, universal: infσ(A)≤0 holds for every self-adjoint extension A, with no sector-regularity hypothesis.
For the Friedrichs extension the operator is unitarily equivalent to the Neumann Laplacian on a spherical lune of opening 2W/R (Proposition 4.2); there Theorem 1.2 is the first nonzero Neumann eigenvalue of the lune, and the mode crossing is the crossing of the two lowest lune branches. What the lune does not capture is the persistence across the bridging family and the extension-dependence of the bottom.
Related work and placement. Two lines of work meet in this model: the quantum mechanics of point interactions and cones, and the spectral geometry of conic extensions.
Point interactions and cone quantum mechanics. The two-dimensional one-center point interaction is classical [AGHH]. On a cone, Kay and Studer [KayStuder] parametrized the apex extension by a length scale and obtained a logarithmic bound-state branch. Our bridging condition is the Kirchhoff-type vertex condition [BK] realizing the corresponding one-center interaction at the conic apex of a curved non-orientable surface: the same logarithmic defect-bound branch appears in the constant sector, now coupled to the Möbius Z2 holonomy and to the width-driven transition, neither of which is present in the single-cone setting. The deformed eigenvalue tower this produces is an instance of the rank-one secular mechanism of Colin de Verdière's pseudo-Laplacians [CdV], here with the interlacing towers explicit. Within the mesoscopic Möbius family, the present model supplies an exactly solvable singular endpoint.
Conic extension theory. The spectral geometry of cone-like singularities begins with Cheeger [Cheeger1979, Cheeger1983], who fixed the Friedrichs extension at such points, and was classified for the model conic metric by Boscain and Prandi [BP]. Our surface sits at their cone parameter αBP=−1, the regime in which the constant angular mode is the distinguished sector carrying the extension ambiguity; in the wide-band case the first odd sector also becomes limit-circle, but the sector-regular class studied here fixes it by the regular Frobenius branch. This is the dichotomy we exploit, together with the holonomy spectra of flat line bundles [BBC]. The closest Möbius-strip predecessor is Kalvoda, Krejčiřík, and Zahradová [KKZ], whose thin-strip analysis of the Dirichlet Laplacian on a curved Möbius strip in R3 yields effective Mathieu dynamics. We differ in two decisive ways: the Neumann condition supplies the constant mode that makes the cone a limit-circle endpoint, and the geodesic core keeps the conic degeneration present at every width. The result is an exact finite-width calculation rather than a thin-strip asymptotic; the common feature with the thin-strip model is the parity bookkeeping imposed by the Möbius holonomy, discussed again in §7.
Against this background, the contribution is not a new extension theory or a new secular method, but the exact assembly of these classical ingredients in the orientation-bundle Möbius geometry, where the extension-dependent bottom and the extension-stable first positive level are computed simultaneously and explicitly.
Method and organization. The proof separates the operator into transverse Neumann sectors and solves each reduced Sturm-Liouville problem in closed form via Legendre functions. Only the constant (zonal) sector carries the cone-condition ambiguity that separates the realizations. Cone parity (reflection about pc, y↦πR−y, equivalently the exchange of the two lune vertices) splits it into a symmetric tower, common to both, and an antisymmetric tower, where they differ. The value 2/R2 comes from the symmetric tower; the zero or negative bottom comes from the antisymmetric tower, where the bridging condition deforms the Friedrichs zero mode through an explicit secular function (§4). The rest of the paper follows this separation. Section 2 sets up the geometric model and Section 3 the operator domain, the extensions, and Friedrichs maximality. We then analyze the zonal sector by parity (§4), assemble the ground-state classification (§5), resolve the nonconstant sectors and the mode crossing (§6), and close with the physical interpretation and limiting regimes (§7).
2. The Geometric Model M(W)
Consider the round 2-sphere S2(R) of radius R. Throughout, R is the curvature radius of this constant-curvature model. Let C be a great circle, and let y denote arclength along a meridian measured from C, so that y=0 and y=πR correspond to antipodal arcs of C reached on opposite sides of the pole at y=πR/2. Let w denote arclength along C, with w∈[−W,W] for a half-width parameter 0<W<πR. The induced metric on the band {(y,w):0≤y≤πR,∣w∣≤W} is
ds2=dy2+cos2(y/R)dw2.
The Gauss curvature is K=1/R2 on the smooth locus and the scalar curvature is Rsm=2/R2.
The Möbius band is obtained from the rectangle [0,πR]×[−W,W] by the single edge identification (0,w)∼(πR,−w). This gluing is the restriction to the edge {y=0} of the isometry τ(y,w)=(πR−y,−w), since τ(0,w)=(πR,−w). The interior 0<y<πR carries no identification, so M(W) is not the quotient of the band by the global involution τ. The result is the non-orientable surface
M(W)=[0,πR]×[−W,W]/(0,w)∼(πR,−w)
with boundary ∂M≅S1, since the two arcs w=±W join into a single closed curve under the identification. The non-orientability arises from the edge identification itself: the seam reverses the boundary coordinate, w↦−w, while the inward normal direction continues across it, so a frame transported around the core loop returns with ∂w↦−∂w and no orientation can be chosen consistently.
At y=πR/2, the metric coefficient cos(y/R) vanishes, collapsing the transverse fiber {y=πR/2}×[−W,W] to a single point pc in the metric space. Both boundary arcs pass through pc (the boundary meridians meet at the pole), so pc∈∂M and the boundary curve has a corner there. The two descriptions of the boundary operate at different levels: ∂M≅S1 refers to the boundary circle of the underlying band, while in the metric space M(W) the image of this circle passes through pc twice, the wedge of two loops described below.
The local model is the one-point union of two half-cones meeting at the apex pc: a punctured neighborhood of pc is disconnected into the y<πR/2 and y>πR/2 halves, since the geodesic distance to pc equals ∣y−πR/2∣ and crossing between halves requires the collapsed fiber, every point of which is pc. The link is two disjoint intervals [−W,W], each of angular length 2W/R; each half-cone has opening angle 2W/R; and the closed boundary curve passes through pc twice, a figure-eight through the apex, with a corner on each side. This two-sided structure is what the four-dimensional cone boundary space and the deficiency count of §3 already encode.
Remark 2.1 (Double-lune realization). There is a complementary fundamental domain that makes the role of the cone conditions geometric. For 0<W<πR/2, let L be the closed spherical lune bounded by the meridians at longitude ±W/R, with vertices at the two poles N and S, and let the double lune be L∪(−L), with −L its antipodal image; the two embedded lunes then meet exactly at the shared vertices. For W≥πR/2 the same construction is understood as an abstract double lune, the embedded lunes no longer meeting only at the vertices. The antipodal map exchanges L with −L and N with S, and the quotient of the double lune by it is the single lune L with its two vertices identified (Figure 1). This quotient is M(W): collapsing the fiber {y=πR/2} and cutting along the seam reassembles the band into L, with the identified vertex pair becoming the cone point pc. The two half-cones of the local model above are the two lune vertices (each of opening 2W/R), and the figure-eight boundary is the two meridians closing through the identified vertex. The picture makes the extension dichotomy of §3.5 geometric: the Friedrichs domain imposes independent regularity conditions at the two lune vertices, so after trivialization its spectrum is the Neumann lune spectrum of Proposition 4.2, without encoding the vertex identification, while the bridging domains impose continuity of the regularized values and Kirchhoff matching of the logarithmic fluxes between the two vertex traces, thereby encoding the quotient identification N∼S.
<img src="https://github.com/dmobius3/mode-identity-theory/blob/main/files/assets/double-lune.png" width="70%" alt="Schematic double-lune realization: double lune on the sphere and its antipodal quotient, a lune with identified vertices">
Figure 1. Schematic double-lune realization of Remark 2.1, narrow case W<πR/2. Left: the double lune L∪(−L) on S2(R), the antipodal lune dashed. Right: the quotient by the antipodal map, a single lune whose two vertices are identified; the identified vertex pair is the cone point pc of M(W), and the two lune sides become the boundary curve through pc.
Under Neumann boundary conditions at w=±W, the transverse problem unfolds onto a circle link of angular circumference 4W/R (§3.4), recovering the circle-link framework of Boscain and Prandi [BP] with parameter αBP=−1. Although pc lies on ∂M as a surface point, it lies at y=πR/2, interior to the longitudinal interval (0,πR). The reduced one-dimensional eigenvalue problems of §§4 and 6 inherit this interior singular-point structure, and the extension theory of §3 applies in full.
The cone angle 2W/R equals π at the critical width W=πR/2. For W<πR/2 (narrow band), the cone angle is less than π; for W>πR/2 (wide band), it exceeds π. As W→πR, each half of the band approaches a hemisphere.
3. Twisted Sections and the Operator Domain
3.1 The orientation line bundle
Real line bundles over M(W) are classified by H1(M;Z2)=Z2 (the band retracts to its core circle): the trivial bundle carries the ordinary scalar Laplacian, and the orientation line bundle L carries the twisted sector studied here, the sign-holonomy sector of the introduction. A smooth function on the parameter rectangle [0,πR]×[−W,W] descends to a section of L→M if and only if it satisfies the equivariance condition
ψ(πR,−w)=−ψ(0,w)for all w∈[−W,W].
This sign reversal is the defining property of a section of L.
The twisted Laplacian is the Laplace-Beltrami operator acting on sections of L. It is the standard Laplace-Beltrami operator on the smooth locus, twisted only in its domain (sections of L rather than functions). The eigenvalue problem −Δψ=λψ is posed for sections of L throughout this paper. Throughout, the analysis lives on the smooth locus M∘=M∖{pc}. Sections are L2 sections over M∘ subject to the seam condition; no value or continuity at pc is imposed unless a self-adjoint extension selects it (§3.5). In particular the discontinuous Friedrichs zero mode of §4 is a legitimate section in this sense: the cone point enters only through the metric completion and through the extension data at the cone traces.
3.2 The formal operator
On the smooth locus M∘=M∖{pc} (where pc denotes the cone point at y=πR/2), the Laplace-Beltrami operator associated to the metric ds2=dy2+f(y)2dw2 with f(y)=cos(y/R) is
The area element is dA=∣f(y)∣dydw, and L2(M,dA) denotes the Hilbert space of square-integrable sections of L with respect to this measure. Although the formal operator is written using f on each smooth coordinate patch, the global measure and the reduced Sturm-Liouville forms use ∣f∣, which is nonnegative across the two sides of the collapsed fiber.
The boundary ∂M consists of two geodesic arcs at w=±W. We impose Neumann boundary conditions: ∂wψw=±W=0.
3.3 The collapsed fiber and the cone point
The cone point pc arises from the metric degeneration alone: at y=πR/2 the coefficient f=cos(y/R) vanishes, so the whole transverse fiber {y=πR/2}×[−W,W] collapses to the single point pc of the metric completion, independently of the edge identification. The reflection δ↦−δ about this fiber (δ=y−πR/2), that is y↦πR−y, is realized by the covering isometry τ(y,w)=(πR−y,−w); its fixed point (πR/2,0) is one point of the collapsed fiber, not pc itself. Thus τ enters the construction in two distinct ways: its restriction to the edge {y=0} is the gluing map of §2, and the reflection δ↦−δ commutes with the reduced operator and organizes the parity decomposition of §4.
At pc, f(πR/2)=cos(π/2)=0. Setting δ=y−πR/2:
f(y)=cos(y/R)=−sin(δ/R)⟹∣f∣∼R∣δ∣as δ→0.
The transverse fiber [−W,W] has metric length 2W∣f(y)∣, which collapses to zero. On the covering S2, the coordinate y=πR/2 is a smooth pole; on the edge-identified Möbius band, the same collapse produces a conical singularity with cone angle 2W/R.
The surface is smooth away from pc, with constant Gaussian curvature K=1/R2 and smooth-locus scalar curvature Rsm=2K=2/R2. Distributional curvature at pc is not invoked in this paper.
3.4 Transverse decomposition and cone asymptotics
Separation of variables ψ(y,w)=u(y)Φ(w) with −Φ′′=μΦ subject to Neumann conditions Φ′(±W)=0 yields two families of transverse eigenmodes on [−W,W].
Even family (symmetric under w↦−w):
Φke(w)=cos(kπw/W),μke=(kπ/W)2,k=0,1,2,…
The case k=0 is the constant mode Φ0e≡1 with μ0=0.
with σ running over the transverse modes Φke, Φjo above. We call the summands Hσtransverse sectors; the constant sector is the k=0 summand, and the qualifiers odd, even, and nonconstant always refer to this decomposition. Proposition 3.7 shows that the realizations studied here reduce over it, so the spectral problem becomes the family of one-dimensional problems treated below. At the L2 level the seam and the collapsed fiber have measure zero, so the decomposition is one of Hilbert spaces only; the periodic or anti-periodic seam condition attached to each transverse parity, and the cone conditions, enter through the reduced operator domains, not through the decomposition itself.
The Möbius identification ψ(πR,−w)=−ψ(0,w) interacts with the transverse parity as follows. For even Φ(w)=Φ(−w), the identification forces u(πR)=−u(0): the longitudinal function is anti-periodic. For odd Φ(−w)=−Φ(w), it forces u(πR)=u(0): the longitudinal function is periodic. In the operator domain the derivative traces inherit the same matching, u′(πR)=−u′(0) in the even case and u′(πR)=u′(0) in the odd case, so the seam is a regular endpoint carrying a self-adjoint anti-periodic or periodic condition.
A Neumann eigenmode on [−W,W] extends by even reflection to a periodic function on the circle link of angular circumference 4W/R in the variable θ=w/R. Labeling harmonics by their index on this circle, the even family Φke carries the even harmonics (index 2k) and the odd family Φjo the odd harmonics (index 2j+1); the k=0 constant mode is the zero harmonic, the analogue of the k=0 Fourier sector in [BP], and the non-essential-self-adjointness of the constant-sector reduced operator at the cone (Theorem 1.6(ii) of [BP]) is the same phenomenon in both settings.
Lemma 3.1 (Neumann unfolding). After the change of angular variable θ=w/R, even reflection at the Neumann endpoints identifies each transverse Neumann eigensector on [−W,W] with a Fourier eigensector on the circle link of angular circumference 4W/R (unitarily, up to a normalization factor from reflection). For each transverse sector, the reduced one-dimensional operator in y has the same singular endpoint at δ=0, the same weight ∣δ∣/R, and the same indicial equation. Since the maximal domain, Lagrange bracket, and deficiency indices depend only on the local behavior at the singular endpoint [Weidmann], the same local boundary data appear as in the Boscain-Prandi cone model [BP], and the Friedrichs and bridging realizations are defined directly from these cone traces in §3.5 (Definition 3.5).
Proof. The Neumann condition at each endpoint of the interval link permits even reflection across both endpoints, producing a periodic function on the doubled link of length 4W/R. This reflection is unitary up to the harmless factor coming from doubling the interval. Near the cone the longitudinal operator depends only on the link eigenvalue μ and on the weight ∣f∣∼∣δ∣/R, so the indicial equation, maximal-domain asymptotics, Lagrange bracket, and limit-point/limit-circle classification are identical to those of the corresponding Fourier sector on the circle-link cone. The cone trace coordinates used below are therefore the same local trace coordinates as in the Boscain-Prandi model. □
In each sector, the reduced eigenequation for the longitudinal function u(y) takes the Sturm-Liouville form
−(∣f∣u′)′+∣f∣μu=λ∣f∣u,f(y)=cos(y/R),
on L2((0,πR),∣f∣dy), where μ is the transverse eigenvalue of the sector. Near the cone (δ→0, ∣f∣∼∣δ∣/R), this becomes
−(R∣δ∣u′)′+∣δ∣μRu=λR∣δ∣u.
Substituting u=∣δ∣s into the leading-order balance gives the indicial equation s2=μR2.
The constant sector (μ=0, even family k=0). The indicial equation gives s2=0 (double root). The two local solutions are
ureg=a0+a2δ2+O(δ4),ulog=log∣δ∣+b2δ2+O(δ4).
Both are square-integrable against the weight ∣δ∣/Rdδ: ∫∣δ∣0⋅∣δ∣dδ<∞ and ∫(log∣δ∣)2⋅∣δ∣dδ<∞. The cone is a limit-circle endpoint, and a self-adjoint extension must be chosen.
Nonconstant sectors with α≥1. Write α=μR for the indicial exponent. When α≥1, the singular branch ∣δ∣−α fails the L2 condition against the weight:
∫u2∣f∣dδ∼∫∣δ∣−2α⋅∣δ∣dδ=∫∣δ∣1−2αdδ=∞for α≥1.
The cone is limit-point. Self-adjointness is unique; no extension choice arises.
Nonconstant sectors with 0<α<1. This regime occurs only for wide bands: W>πR/2 for the j=0 odd mode. Both branches ∣δ∣±α are now L2 against the weight (since 1−2α>−1). The cone is limit-circle. The branches are distinguished by the Dirichlet energy. For the singular branch u=∣δ∣−α,
∫(u′)2∣f∣dδ∼α2∫∣δ∣−2α−1dδ=∞for all α>0,
so the singular branch has infinite Dirichlet energy. The Friedrichs extension selects the regular branch ∣δ∣+α, the unique branch of finite Dirichlet energy, and every realization of finite Dirichlet energy in this sector coincides with it there.
The limit-point/limit-circle classification at a singular endpoint depends only on the local behavior of the coefficients [Weidmann, KSWW], and the local expansions are regular-singular in the sense of Brüning and Seeley [BS]. Near pc, the weight ∣f∣ vanishes linearly in δ, matching the flat-cone case αBP=−1 in the notation of [BP]. On the model cone of [BP] (angular period 2π) only k=0 has α<1; the unfolded period 4W/R adds the wide-band first odd sector, with exponent α0=πR/(2W), to the limit-circle list. The extension structure this produces is recorded in Lemma 3.3 below.
Remark 3.2 (Continuity heuristic for the constant sector). If a continuous section ψ=u(y)Φ(w) has nonconstant transverse profile Φ, then u(πR/2)=0: the collapsed fiber is a single point of M(W), and a nonzero apex value would assign it several values. The constant mode alone tolerates a nonzero apex value, which is the geometric reason why, once the regular branch is fixed in every nonconstant sector (Definition 3.5), the residual extension freedom lives in the constant sector. The operative criterion, however, is the limit-point/limit-circle classification above, not continuity: the actual ground states, the discontinuous ϕ0 and the logarithmically divergent bridging mode, both fail continuity at pc.
Lemma 3.3 (Wide-band odd-sector endpoint). For 0<W≤πR/2 every nonconstant transverse sector is limit-point at pc and the minimal operator has total deficiency indices (2,2), carried entirely by the constant sector. For πR/2<W<πR the first odd sector, with indicial exponent α0=πR/(2W)<1, is in addition limit-circle, and the total indices are (4,4). Under the Liouville substitution v=∣f∣1/2u the reduced operator of that sector is −v′′+gδ−2v+O(1) near the cone, with inverse-square coupling g=α02−41∈(−41,43). Every sectorwise self-adjoint realization of this inverse-square endpoint is bounded below.
Proof. The classification follows from ∣f∣∼∣δ∣/R and the indicial equation s2=μR2, whose roots are s=±α0: for α0≥1 the singular root leaves L2 (limit-point), for 0<α0<1 both roots are square-integrable (limit-circle), and at W=πR/2 exactly α0=1, so the count stays (2,2). The substitution v=∣f∣1/2u sends −(∣f∣u′)′+(μ/∣f∣)u to −v′′+gδ−2v+O(1) with g=s2−41=α02−41. For g>−41 Hardy's inequality makes the local form nonnegative, and on the finite interval with one regular (seam) endpoint the deficiency is finite, so each self-adjoint realization differs from the Friedrichs one by at most finitely many eigenvalues and is bounded below [KSWW, RS]. □
Remark 3.4 (Aharonov-Bohm flux analogy). In the flat-line-bundle/Aharonov-Bohm language of the introduction, the wide-band effect is the geometric analogue of lowering the shifted angular momentum at a flux line. The π holonomy shifts the transverse-longitudinal pairing by half a unit, and widening the band drags the lowest shifted momentum into the limit-circle window at the origin.
Neither finite Dirichlet energy nor semiboundedness alone singles out a realization in the wide band: the constant-sector logarithmic mode of §4.4 has infinite Dirichlet energy, and by Lemma 3.3 the singular-branch odd extensions are semibounded as well. We therefore work only with realizations that select the regular (Frobenius) branch in every nonconstant sector, the Friedrichs choice there, and we do not treat realizations that couple distinct transverse sectors. The reduction of every extension question to the cone traces of the individual sectors rests on the unfolding equivalence of Lemma 3.1. The two we single out, the Friedrichs and bridging realizations, are defined in §3.5 (Definition 3.5).
3.5 The cone boundary form and point-interaction extensions
Once the regular Frobenius branch is fixed in every nonconstant sector (§3.4), the only remaining extension choice that distinguishes Friedrichs from bridging lies in the constant sector (μ=0), where both local solutions are L2. Near the cone, the general constant-sector solution has the asymptotic form
u(δ)=uNln2R∣δ∣+uD+o(1)(δ→0),
with a log coefficient uN (the flux datum) and a regularized value uD (referenced to the length 2R), independently on each side of the cone. We write uD± and uN± for the limits from δ→0±.
The 1/R normalization is fixed directly by the two local branches. Take ureg=1+O(δ2) (so uN=0, uD=1) and ulog=ln(∣δ∣/2R)+O(δ2) (so uN=1, uD=0); with ∣f∣∼∣δ∣/R the weighted Wronskian is
so the Lagrange bracket of the regular and log branches at the apex is [ureg,ulog]pc=1/R on each side. Both branches are square-integrable against ∣f∣dδ (§3.4), so each of the two half-cones contributes a two-dimensional cone trace (uD±,uN±), and together they span the four-dimensional boundary space (uD+,uN+,uD−,uN−). This is obtained from the model's own weight ∣f∣=∣cos(y/R)∣ and the indicial data of §3.4; the circle-link cone of [BP] carries the same local structure.
The cone boundary form produced by Green's identity is
[u,v]pc=R1∑±(uD±vN±−uN±vD±),
where the logarithmic divergences cancel pairwise: a direct computation from the near-cone reduced form gives ∣f∣(uv′−u′v)→(sgnδ/R)(uDvN−uNvD) as δ→0, and the two-sided Green identity sums these limits with the outward-normal orientation, yielding the boundary form above. The normals fix the overall sign; a global sign only rescales the symplectic form, leaving its Lagrangian planes unchanged. A self-adjoint extension corresponds to a two-dimensional Lagrangian plane (a subspace on which this boundary form vanishes identically) in the four-dimensional boundary space (uD+,uN+,uD−,uN−). The extension data here are the cone traces alone; the regular arcs w=±W carry their fixed Neumann condition and enter no extension choice.
The Friedrichs (disjoint) extension. The Friedrichs extension [Friedrichs] is characterized by Theorem 1.8 of [BP] (applied at αBP=−1): its domain requires
uN+=0anduN−=0,
with no condition relating uD+ to uD−. This is two conditions on four parameters, and the plane {uN+=uN−=0} is Lagrangian: the boundary form vanishes when both fluxes are zero. The domain imposes no matching condition at pc, so the two cone traces uD± are unconstrained and the constant-sector form q0 decomposes as q0+⊕q0− on the two halves M±={±(y−πR/2)>0} (coupled only through the seam identification, not through pc). This is the "disjoint dynamics" case c+=c−=0 of [BP].
The bridging extension at renormalization length δ0. Boscain and Prandi (Theorem 1.8 of [BP]) classify the conic extensions into a disjoint family and a mixed family, the mixed one parametrized by K∈SL2(R); their Remark 1.9 names the K=Id case the bridging extension. To equip this condition with a renormalization length δ0>0, we use the standard two-dimensional point-interaction renormalization [AGHH, KayStuder]. In the conic trace coordinates this means re-expressing the data relative to δ0,
u(δ)=uNlnδ0∣δ∣+u~D+o(1),u~D=uD+uNln2Rδ0,
and imposing
u~D+=u~D−(continuity of the regularized value),
uN++uN−=0(Kirchhoff flux matching).
This is two conditions on four parameters. The plane is Lagrangian: since uD±=u~D±−uN±ln(δ0/2R), the ln(δ0/2R) terms cancel pairwise in the boundary form, and for u,v both satisfying the bridging conditions,
[u,v]pc=R1[u~D(vN++vN−)−v~D(uN++uN−)]=0.
The value condition is continuity across the cone; the flux condition is the sign-flipped (Kirchhoff) matching dictated by the opposite outward normals on the two sides. Different choices of δ0 yield distinct self-adjoint extensions with distinct spectra. In the fixed trace coordinates (uD±,uN±) the family sweeps a one-parameter family of Lagrangian planes, each the K=Id condition expressed in its own δ0-renormalized coordinates. The renormalization length is a genuine parameter, set neither by the metric nor by the bundle alone.
Definition 3.5 (Sector-regular realizations). A self-adjoint realization of the twisted Laplacian is sector-regular if at pc it selects the regular (Frobenius) branch in every nonconstant transverse sector. We use two. The Friedrichs extensionΔF takes the regular branch in the constant sector as well. For each δ0>0 the bridging realizationAδ0br takes in the constant sector the logarithmic matching u~D+=u~D−, uN++uN−=0 at renormalization length δ0 (the condition above), and the regular branch in every nonconstant sector. These realizations are self-adjoint; ΔF is nonnegative (§3.6), and §4.4 shows that Aδ0br is semibounded with bottom λb(δ0)<0. In the wide band both additionally take the regular (Frobenius) branch in the first odd sector, so they lie within the (4,4)-family of Lemma 3.3, while the realizations that activate the singular odd branch are not sector-regular. Sector-regularity fixes every nonconstant branch but leaves the constant-sector cone condition free, so ΔF and Aδ0br are two distinguished sector-regular realizations, not an exhaustive pair.
Remark 3.6 (Scattering dictionary). In the point-interaction language of [AGHH, KayStuder], sector-regularity confines the defect interaction to the s-wave, i.e. the constant angular channel. Every other channel, including the wide-band first odd one, is held at the regular branch, so the width transition remains a holonomy/geometry effect rather than a second point-interaction parameter.
For any constant c=0, the discontinuous piecewise-constant section
ϕ0(y,w)={+c−cif y<πR/2,if y>πR/2,
has uN±=0 and u~D+=−c=+c=u~D−, so it lies in the Friedrichs domain (it satisfies the Friedrichs flux conditions) but is excluded from every bridging domain (it fails value-continuity). Since −Δϕ0=0 on the smooth locus and ϕ0 satisfies the equivariance condition, it is a genuine eigenfunction with eigenvalue 0 for the Friedrichs extension: a domain wall pinned at the defect. Its transverse profile is constant, so it lies in the constant sector.
The covering geometry constrains, but does not by itself fix, the extension. A section of L that lifts to a function smooth at the pole of the covering S2 is regular there (uN=0) and even in δ; this forces the regular branch in the symmetric subsector (§4.2) but does not determine the cone condition in the antisymmetric subsector, where the natural candidates are the Friedrichs and bridging conditions above. The remaining choice is the antisymmetric cone condition, which is what separates Friedrichs from bridging in §5.
Proposition 3.7 (Operator realization). The formal twisted Laplacian commutes with the transverse Neumann Laplacian, since cos2(y/R) depends on y alone. The Friedrichs extension and the sector-regular bridging realization Aδ0br impose cone conditions sector by sector, so the transverse Neumann decomposition L2(M,dA)=⨁σHσ reduces both operators. In each sector the reduced Sturm-Liouville operator in y, with the seam condition from anti-equivariance and the cone condition of Definition 3.5, is self-adjoint with compact resolvent. The sector bottoms diverge, so each direct sum is self-adjoint with compact resolvent and discrete spectrum. Thus ΔF and Aδ0br are these orthogonal direct sums.
Proof. Commutation gives the reducing decomposition, and the form closure respects it: each transverse spectral projection maps the core into itself with ∑σq[Pσψ]=q[ψ] by Parseval in w, so the closed form is the orthogonal sum of the sector forms. Each reduced operator is regular-singular on a finite interval with integrable weight ∣f∣; by §3.4 the cone is limit-point in every sector except the constant one and, for W>πR/2, the first odd one (Lemma 3.3), where Definition 3.5 imposes a self-adjoint cone condition. So each sector operator is self-adjoint with compact resolvent [Weidmann], and since the sector bottoms tend to infinity (established at the end of §6.2) the orthogonal direct sum has compact resolvent. □
3.6 Friedrichs maximality
Friedrichs maximality is a statement about a fixed lower-semibounded symmetric operator, which we name here. Let Tmin, the minimal twisted Laplacian, be the closure in L2(M(W),L) of −Δ acting on smooth anti-equivariant sections that vanish in a neighborhood of the cone point pc and satisfy the Neumann condition ∂wψw=±W=0. It is densely defined, symmetric, and nonnegative (the form q below is ≥0 on its domain), and its only locus of non-essential-self-adjointness is pc, every boundary arc being a regular endpoint (§3.4). The Friedrichs extensionΔF is the Friedrichs extension of Tmin, and qF is the closure of the form ψ↦⟨Tminψ,ψ⟩ in the form norm ∥⋅∥q of the associated quadratic form q below. Imposing ∂wψ=0 pointwise on the operator core does not shrink the form domain: the form carries no boundary term at the arcs, and smooth sections with vanishing normal derivative there are dense in form norm among all smooth sections (flattening the transverse parametrization near a regular arc changes the energy arbitrarily little), so the closure returns the same D(qF) obtained below from the free core C.
The Dirichlet form on M(W)
q[ψ]=∫M∘∣∇ψ∣2dA,M∘=M(W)∖{pc},
is nonnegative on the core C of smooth anti-equivariant sections on the closed smooth locus M∘, smooth up to the boundary arcs w=±W with no condition imposed there, and with support compact in M∘∖{pc} (excised only at the cone). The free arcs make the Neumann condition natural: ∂wψw=±W=0 is recovered from q on closure, whereas a core of support compact in the open manifold would close to Dirichlet data at w=±W and remove the constant transverse mode. The Friedrichs extension ΔF is the self-adjoint operator associated with the closure of q on C: "Friedrichs" designates the extension at the cone pc, the only locus of extension ambiguity (§3.5), the arcs keeping their Neumann condition throughout. Its form domain D(qF)=C∥⋅∥q is contained in the form domain of every self-adjoint extension at the cone whose form is bounded below by that of q; by finite deficiency every extension here is semibounded, so after a shift this covers them all (§5).
Lemma 3.8 (Friedrichs maximality). Let A be any self-adjoint extension of the minimal twisted Laplacian on M(W).
(i) The minimal operator is nonnegative, and ΔF is its largest nonnegative extension in the Birman-Krein-Vishik order [AlonsoSimon]: D(qF)⊆D(qA) for every nonnegative extension A, so by min-max λn(A)≤λn(ΔF) for all n, and in particular infσ(A)≤infσ(ΔF).
(ii)infσ(ΔF)=0: the form q≥0 gives infσ(ΔF)≥0, and ϕ0∈D(ΔF) with ΔFϕ0=0 (Lemma 4.1) gives infσ(ΔF)≤0.
(iii) Consequently infσ(A)≤0 for every self-adjoint extension A: for nonnegative A by (i)–(ii), and for non-nonnegative A by definition. The argument uses only nonnegativity of the minimal operator, with no parity hypothesis.
Proof. (i) is the Birman-Krein-Vishik characterization of the Friedrichs extension as the largest nonnegative self-adjoint extension of a nonnegative symmetric operator [AlonsoSimon]: its form domain D(qF)=C is contained in D(qA) for every nonnegative extension A, and a smaller form domain yields larger Rayleigh quotients, so λn(A)≤λn(ΔF) by min-max. (ii) The cutoff estimate of Lemma 4.1 below shows ϕ0∈D(ΔF) with ΔFϕ0=0, so infσ(ΔF)≤0; and q≥0 gives infσ(ΔF)≥0. (iii) Immediate. □
Lemma 3.8 proves the part of Theorem 1.1 that needs no separation of variables: every realization has bottom at most 0.
4. The Zonal Sector by Parity: Zero Mode versus Defect Bound State
The constant transverse mode (k=0 even family, Φ0e≡1) reduces the eigenvalue problem to a single ODE in y with anti-periodic boundary conditions. This is the zonal sector, where the Friedrichs and bridging realizations differ. We analyze it by parity about the cone.
4.1 The reduced operator and parity reduction
On the constant-curvature band, the zonal eigenequation from §3.4 with μ=0 is
−Δu=−u′′+R1tan(Ry)u′=λuon (0,πR),
with anti-periodic boundary conditions u(πR)=−u(0) and u′(πR)=−u′(0), and a cone condition at y=πR/2 from §3.5. Decompose the constant-sector functions into modes symmetric and antisymmetric under reflection about the cone δ↦−δ. Anti-periodicity interacts with this parity as follows.
Symmetric modes satisfy u(πR)=u(0) automatically, so the anti-periodic value condition forces u(0)=0 (Dirichlet at the seam), while the derivative condition u′(πR)=−u′(0) is then free. The symmetric sector is the half-interval problem on (0,πR/2) with Dirichlet at the seam and a cone condition.
Antisymmetric modes satisfy u(πR)=−u(0) automatically, so the value condition is free and the derivative condition forces u′(0)=0 (Neumann at the seam). The antisymmetric sector is the half-interval problem on (0,πR/2) with Neumann at the seam and a cone condition.
On the bridging side, a symmetric mode has equal log coefficients on the two sides, so the Kirchhoff flux condition forces the log coefficient to vanish, and the symmetric mode lies in the Friedrichs domain. An antisymmetric mode has u~D+=−u~D−, so the value-continuity condition forces u~D=0, and the log datum is active. The two subsectors decouple: the symmetric subsector gives the same spectrum for the Friedrichs and bridging extensions and is treated in §4.2; the antisymmetric subsector is where these extensions differ and is treated in §§4.3–4.4. The resulting constant-sector parity dictionary:
parity about pc
half-interval seam condition
active cone datum (bridging)
symmetric
Dirichlet, u(0)=0
none (uN=0 forced)
antisymmetric
Neumann, u′(0)=0
u~D=0 (log datum active)
4.2 Legendre reduction and the symmetric tower
The substitution x=sin(y/R) maps (0,πR/2) bijectively to (0,1) and converts the zonal operator to the Legendre equation. With u(y)=v(sin(y/R)),
<div align="center">
dxd[(1−x2)dxdv]+ν(ν+1)v=0,λ=R2ν(ν+1)
</div>
where ν≥0 is a continuous spectral parameter. The Legendre function of the first kind Pν(x) is regular at x=1 (the cone); the Legendre function of the second kind Qν(x) diverges logarithmically and supplies the log datum uN. The substitution x=sin(y/R) is two-to-one (y and πR−y map to the same x) and produces exactly the modes symmetric about the cone.
In the symmetric subsector both the Friedrichs and bridging conditions force the regular branch (the log coefficient vanishes, by §4.1), so the admissible symmetric solutions are Pν(sin(y/R)). The Dirichlet seam condition u(0)=0 is Pν(0)=0. Since
<div align="center">
Pν(0)=Γ((1−ν)/2)Γ(1+ν/2)π
</div>
[DLMF, Eq. 14.5.1], this holds exactly when (1−ν)/2 is a non-positive integer, i.e. ν=1,3,5,… The symmetric zonal tower is therefore
<div align="center">
σsym={R2ℓ(ℓ+1):ℓ=1,3,5,…}={R22,R212,R230,…}
</div>
the same for the Friedrichs and bridging extensions. The lowest member is ℓ=1, with eigenfunction P1(sin(y/R))=sin(y/R), the restriction of the zonal harmonic Y10∝sin(y/R). It is strictly positive on (0,πR), lies in the regular Frobenius branch at the cone, and gives
<div align="center">
R2ℓ(ℓ+1)ℓ=1=R22=Rsm
</div>
independent of the half-width W.
On the flat strip (Euclidean metric, anti-periodic condition, same period πR), the lowest eigenvalue is 1/R2=Rsm/2, with the same eigenfunction sin(y/R). The curvature term (1/R)tan(y/R)u′ doubles this to 2/R2=Rsm, matching the familiar ℓ=1 eigenvalue on S2(R).
4.3 The Friedrichs antisymmetric tower and the kernel
Under the Friedrichs extension, the antisymmetric subsector (Neumann seam, regular cone) admits sgn(δ)Pν(sin(y/R)) with the regular branch at the cone, and the Neumann seam condition is Pν′(0)=0, i.e. ν=0,2,4,… The Friedrichs antisymmetric tower is
<div align="center">
σantiFr={R2ℓ(ℓ+1):ℓ=0,2,4,…}={0,R26,R220,…}
</div>
The ℓ=0 member is sgn(δ)P0=sgn(δ), a scalar multiple of the zero mode ϕ0: odd about the cone, as the antisymmetric subsector requires.
Lemma 4.1 (Friedrichs kernel in the constant sector). In the constant transverse sector, the Friedrichs form decomposes as the direct sum of the two half-band forms on M+ and M−. Consequently ϕ0 belongs to D(ΔF) and satisfies ΔFϕ0=0, and the zero eigenspace in the constant sector is one-dimensional, spanned by ϕ0.
Proof. Let χε(δ) be smooth, equal to 0 for ∣δ∣≤ε, equal to 1 for ∣δ∣≥ε, and satisfying ∣χε′(δ)∣≤C/(∣δ∣∣logε∣) for ε<∣δ∣<ε. Since ∣f(y)∣∼∣δ∣/R at the cone, the cutoff energy (the transverse integration contributing only the constant factor 2W) obeys
Thus the jump of ϕ0 across the collapsed point is invisible to the Friedrichs form closure: χεϕ0→ϕ0 in the form norm, so ϕ0∈D(qF) and qF(ϕ0,η)=0 for every form-domain test section η, whence ϕ0∈D(ΔF) and ΔFϕ0=0. By contrast the logarithmic branch has u′(δ)∼1/δ, hence ∫∣u′∣2∣f∣dδ∼∫dδ/∣δ∣=∞, and is excluded from the Friedrichs domain. Conversely, if qF[ψ]=0 in the constant sector then ∇ψ=0 a.e. on each connected half, so ψ is constant on each of M±; the anti-periodic seam condition forces the two constants to be opposite, giving a scalar multiple of ϕ0. □
Proposition 4.2 (Lune equivalence). For the Friedrichs extension, multiplication by the trivializing section, Uψ=ϕ0⋅ψ with ϕ0 the unit-modulus zero mode (c=1), is a unitary operator from L2(M(W),L) onto L2 of the spherical lune of opening angle 2W/R, and it restricts to a unitary from the Friedrichs form domain D(qF) onto the Neumann form domain H1 of the lune. Consequently the Friedrichs twisted Laplacian ΔF is unitarily equivalent to the Neumann Laplacian of the lune, with ϕ0 carried to the constant function. The equivalence is specific to the Friedrichs extension: no bridging realization is unitarily equivalent to the lune Neumann Laplacian, under U or under any other unitary map.
Proof.Trivialization and L2 unitarity. Over the smooth locus M∘ the bundle L is trivial, and ϕ0 (with c=1) is the trivializing section. Set ψ~=ψ on {y<πR/2} and ψ~=−ψ on {y>πR/2}; in coordinates t=y on the first half and t=y−πR on the second (with w′=w and w′=−w respectively), the anti-equivariance condition becomes plain continuity of ψ~ across t=0, and the metric becomes dt2+cos2(t/R)dw′2 on the lune of opening 2W/R (t∈(−πR/2,πR/2), w′∈[−W,W]). The anti-periodic seam maps to interior continuity and the Neumann edges w=±W to the two geodesic Neumann sides of the lune, both away from the poles. Since ∣ϕ0∣=1 a.e., ∥Uψ∥L2=∥ψ∥L2, and U is unitary onto L2 of the lune.
Energy isometry on the smooth locus. On M∘, ∇ϕ0=0 and ∣ϕ0∣=1, so ∣∇(ϕ0ψ)∣=∣∇ψ∣ pointwise. Hence U maps the core C onto the corresponding core on the lune (smooth functions, free at the Neumann sides, supported away from the poles), preserving both ∥⋅∥L2 and the energy q; it is a ∥⋅∥q-isometry of these test spaces.
Form-domain identification via zero capacity. By definition D(qF)=C∥⋅∥q. Each pole is a single point and has zero 2-capacity: the same logarithmic cutoff χε as Lemma 4.1, whose energy is O(∣logε∣−1)→0, shows that the smooth functions on the lune supported away from the poles are H1-dense in H1 of the lune. Taking ∥⋅∥q-closures, U is unitary from D(qF) onto H1 of the lune. Thus U intertwines the closed forms and the associated self-adjoint operators, and ϕ0 maps to the constant.
Friedrichs-specificity. The mode ϕ0 is discontinuous at the cone, so it satisfies the Friedrichs flux conditions but fails the bridging value-continuity u~D+=u~D−; and every bridging form domain contains the logarithmic mode u′∼1/δ, whose raw Dirichlet energy ∫(u′)2∣f∣dδ∼∫dδ/∣δ∣ diverges, so its image is not in H1 of the lune. Hence U is not unitary onto the lune Neumann form domain for any bridging extension. More strongly, no unitary map at all can intertwine them: spectra are unitary invariants, the lune Neumann Laplacian is nonnegative, and every bridging realization at finite δ0 carries the negative eigenvalue λb(δ0). □
The trivialization and the zero-capacity estimate are sector-independent, so the equivalence is for the full Friedrichs operator, with the sector towers organized by longitude order. The Friedrichs spectrum is therefore the lune Neumann spectrum, obtained by separation of variables: longitude Neumann modes of order mn=nπR/(2W) combined with colatitude Legendre functions regular at both poles give eigenvalues (mn+ℓ′)(mn+ℓ′+1)/R2 for n,ℓ′≥0. In particular, for the Friedrichs realization the first positive eigenvalue of Theorem 1.2 is the first nonzero Neumann eigenvalue of this lune: the (n,ℓ′)=(0,1) and (1,0) modes give 2/R2 and α0(α0+1)/R2, crossing doubly at W=πR/2. The width transition is thus the crossing of the two lowest lune branches. Explicit Legendre analyses of lune and spherical-triangle spectra are a classical and active subject: Seto, Wei, and Zhu [SWZ] compute Dirichlet eigenvalues and eigenfunctions of spherical lunes and triangles in the same Legendre framework. What Proposition 4.2 adds is the identification of the twisted-bundle problem with the Neumann lune problem, and its failure for every bridging extension.
4.4 The deformed antisymmetric branch
The bridging extension deforms the Friedrichs antisymmetric tower. By §4.1, the antisymmetric subsector under bridging is the half-interval problem on (0,πR/2) with Neumann at the seam and the regularized condition u~D=0 at the cone. Let uλ denote the solution of the zonal equation on (0,πR/2) normalized by uλ′(0)=0, uλ(0)=1. Near the cone it has the expansion
uλ(δ)=N(λ)ln2R∣δ∣+D(λ)+o(1),
with N(λ) the log coefficient and D(λ) the regularized value, both real-analytic.
The reference length 2R is not a free normalization: it is fixed by the near-cone behavior of the Legendre function of the second kind. As x→1−,
Qν(x)=−21ln21−x−γ−ψ(ν+1)+O((1−x)ln(1−x))
[DLMF, Eq. 14.8.3], the Ferrers function of the second kind on (−1,1), the same convention as the Pν′(0), Qν′(0) values below. With x=sin(y/R) and δ=y−πR/2 one has x=cos(δ/R), so 1−x=δ2/(2R2)+O(δ4) and 21ln21−x=ln2R∣δ∣+o(1). Hence
Qν(sin(y/R))=−ln2R∣δ∣−γ−ψ(ν+1)+o(1),
the residual being O((δ2/R2)ln∣δ∣). This is where the length 2R enters the constant-sector expansion of §3.5. It is the square root of the 1/(4R2) prefactor in (1−x)/2. The expansion is even in δ, since x=cos(δ/R) is. The same 2R therefore governs both sides δ→0±, matching the two-sided bookkeeping of §3.5. The regular branch Pν(x)→1 contributes only to D(λ), while Qν supplies the log datum N(λ) and the constant −γ−ψ(ν+1) in D(λ). The same 2R accordingly fixes the threshold δ0=2R/e of Proposition 4.4 and the constant in λb=−4e−2γ/δ02. A different reference length would shift these constants in lockstep, leaving the eigenvalues themselves invariant.
Define the secular function
G(λ)=−N(λ)D(λ).
Since the data referenced to δ0 satisfy u~D=D(λ)+N(λ)ln(δ0/2R) (the δ0-rescaling above), the bridging eigenvalue condition u~D=0 is
G(λ)=ln2Rδ0.
This is the classical secular mechanism for rank-one domain perturbations: G is a Herglotz-type function whose poles lie at the unperturbed tower and whose level sets give the deformed eigenvalues, exactly as for the pseudo-Laplacians of Colin de Verdière [CdV] and the point interactions of [AGHH]. The closed forms below make every element of the mechanism explicit.
For ν>−1/2 (equivalently λ>−1/(4R2)), the substitution x=sin(y/R) and the Legendre closed forms give
G(ν(ν+1)/R2)=−γ−ψ(ν+1)−Pν′(0)Qν′(0),
where γ is the Euler-Mascheroni constant and ψ=Γ′/Γ the digamma function (distinct from the section ψ). The derivative values at the origin,
[DLMF, Eqs. 14.5.2 and 14.5.4], share the same Gamma quotient, which cancels in the ratio, leaving
G(ν(ν+1)/R2)=−γ−ψ(ν+1)−2πcot2πν.
The cotangent has poles at the even integers ν=0,2,4,…, which are exactly the Friedrichs antisymmetric tower; there G has simple poles.
For λ<−1/(4R2), write ν=−21+iκ with κ=(−λR2−41)1/2. The closed form continues real-analytically. With cot(−4π+2iπκ)=−sech(πκ)−itanh(πκ) and Imψ(21+iκ)=2πtanh(πκ), the imaginary parts cancel exactly, giving
G(λ)=−γ−Reψ(21+iκ)+2πsech(πκ),λ≤−4R21.
Lemma 4.3 (Monotonicity).G is strictly increasing between consecutive poles; on each interval between consecutive poles it is a bijection onto R, and on (−∞,0) it has no poles and increases from −∞ to +∞.
Proof. A Green identity on (0,πR/2) for the Neumann-normalized solutions at distinct parameters gives, after the log terms cancel in the cone bracket and the seam bracket vanishes by the shared Neumann data,
(λ′−λ)∫0πR/2∣f∣uλuλ′dy=RN(λ′)D(λ)−N(λ)D(λ′),
whence G′(λ)=R∥uλ∥∣f∣2/N(λ)2>0 at points where N(λ)=0; at the even integers, where N=0, G has simple poles, and monotonicity is asserted on each open interval between consecutive poles. At each even-integer pole ν=2n the finite part −γ−ψ(ν+1) stays bounded while −2πcot(πν/2)∼−1/(ν−2n), so G→+∞ as the pole is approached from below (ν→2n−, with λ increasing toward it) and G→−∞ from above (ν→2n+); with G′>0 in between, G increases from −∞ to +∞ across each interval between consecutive poles and is a bijection onto R there. The poles of G are the even integers, which are nonnegative; so G has no pole on (−∞,0). The deep-negative asymptotic from ψ(z)=lnz−1/(2z)+O(z−2) gives G(λ)=−γ−21ln(−λR2)+O((−λR2)−1)→−∞ as λ→−∞, while G→+∞ as λ→0− (the pole at ν=0). Strict monotonicity makes G a bijection on (−∞,0). □
Proposition 4.4 (Bridging constant-sector spectrum). For every δ0>0, the constant sector of Aδ0br has exactly one negative eigenvalue
λb(δ0)=−δ024e−2γ(1+O(δ02/R2))(δ0→0+),
a cone-localized bound state independent of the half-width W and strictly increasing in δ0 with λb→0− as δ0→∞. Zero is not an eigenvalue: it lies in the resolvent set. The symmetric tower is unchanged, and the deformed antisymmetric eigenvalues interlace the Friedrichs tower, one in each gap. Moreover, for
δ0>e2R
the lowest positive eigenvalue of the constant sector is 2/R2 and simple; at δ0=2R/e it is still 2/R2 but doubly degenerate within the constant sector, the deformed antisymmetric root coinciding with the symmetric ℓ=1 value (combined with the odd j=0 sector this produces the threshold triple degeneracy of Corollary 6.3 when also W=πR/2), and for δ0<2R/e it lies strictly below 2/R2.
Proof. By Lemma 4.3, G is a bijection of (−∞,0) onto R, so the secular condition has exactly one negative root for every δ0. Solving the deep asymptotic against ln(δ0/2R) gives the bound state λb(δ0), and G′>0 gives monotonicity in δ0 with λb→0− as δ0→∞. At λ=0 the Neumann-seam solution is u0≡1, with N(0)=0 and D(0)=1=0, so u~D=1=0 and the bridging condition excludes λ=0. On each interval between consecutive poles (the Friedrichs tower) G is a bijection onto R, giving one deformed root per gap. Finally, at ν=1 (λ=2/R2), cot(π/2)=0, so G(2/R2)=−γ−ψ(2)=−γ−(1−γ)=−1; since G is increasing on (0,6/R2), the lowest positive deformed root exceeds 2/R2 for ln(δ0/2R)>−1 and equals 2/R2 at ln(δ0/2R)=−1, so for δ0>2R/e the lowest positive eigenvalue of the sector is 2/R2 and simple, while at δ0=2R/e it remains 2/R2 with the deformed root coincident. □
Every deformed antisymmetric eigenfunction has N=0, hence diverges like Nln(∣δ∣/δ0) at the cone; in particular the bound state at λb is nodeless on each open half (it is the lowest eigenfunction of the half-interval problem, hence positive there by oscillation theory [Weidmann]), with opposite signs on the two halves and a logarithmic divergence at pc. It vanishes nowhere on the smooth locus. The constant −4e−2γ in λb is the standard two-dimensional one-center point-interaction binding energy [AGHH], with δ0 in the role of the point-interaction renormalization length. Matching the logarithmic scale identifies δ0 with the coupling parameter of the one-center family of [AGHH, KayStuder]; in the present finite curved cone it realizes the same renormalized constant-channel interaction, with the global Legendre geometry supplying the exact secular correction. Figure 2 displays the two constant-sector branches as functions of the renormalization length, computed from the exact secular condition.
<img src="https://github.com/dmobius3/mode-identity-theory/blob/main/files/assets/delta0-branches.png" width="80%" alt="The defect-bound state and the lowest deformed root of the bridging realization as functions of the renormalization length, with the 2R/e threshold marked">
Figure 2. The two constant-sector branches of the sector-regular bridging realization as functions of the renormalization length, computed from the exact secular condition G(λ)=ln(δ0/2R) of §4.4: the defect-bound state λb(δ0), with its point-interaction asymptotic −4e−2γ/δ02 (dashed; the asymptotic is a small-δ0 statement, and the visible deviation at moderate δ0 is the O(δ02/R2) correction of Theorem 1.1), and the lowest deformed antisymmetric root. For δ0>2R/e the deformed root lies above the width-independent zonal level 2/R2 (dotted), so the lowest positive constant-sector level is 2/R2, the input to Theorem 1.2; at δ0=2R/e the two coincide (marked).
5. Ground-State Dependence on the Cone Interaction
We now assemble the zonal analysis into the ground-state classification.
Theorem 5.1 (Bottom of the spectrum across realizations). Let A be any self-adjoint extension of the minimal twisted Laplacian on M(W), 0<W<πR. Then:
(i)infσ(A)≤0, with no self-adjoint extension having strictly positive spectral bottom.
(ii)infσ(A)=0 if and only if A is nonnegative; the Friedrichs extension is the maximal such realization, with infσ(ΔF)=0 attained by the discontinuous zero mode ϕ0.
(iii) For the sector-regular bridging realization Aδ0br, infσ=λb(δ0)<0, a single cone-localized defect bound state; zero lies in the resolvent set.
For the Friedrichs and bridging extensions the symmetric zonal tower is unchanged, and their difference lives entirely in the antisymmetric subsector; a general parity-mixing Lagrangian cone condition can instead deform the symmetric subsector. Parts (ii)–(iii) give the explicit bottom for the nonnegative and bridging realizations, while part (i) holds for every self-adjoint extension, the parity-mixing and singular-odd-branch realizations included.
Proof. Part (i) is Lemma 3.8(iii), which bounds infσ(A)≤infσ(ΔF)=0 for nonnegative A and is immediate for non-nonnegative A. The mechanism is also visible directly: since the minimal operator is nonnegative and has finite deficiency indices, every self-adjoint extension here is semibounded [AlonsoSimon]; after shifting such an extension to be nonnegative, the Birman-Krein-Vishik order gives D(qF)⊆D(qA) with the form agreeing with qF there, and since ϕ0∈D(qF) has zero energy, infσ(A)≤0 with no maximality argument needed. Part (ii): if A is nonnegative then infσ(A)≥0; combined with (i) this forces infσ(A)=0, and Lemma 3.8(i) identifies Friedrichs as the maximal nonnegative realization, with the bottom attained by ϕ0 (Lemma 4.1). Part (iii) is Proposition 4.4 for the constant sector; under the sector-regular convention every nonconstant sector is nonnegative (its bottom is α(α+1)/R2>0 for α>0, §6), so the full-operator bottom is the constant-sector bottom λb(δ0)<0, with zero in the resolvent set. The robustness of the symmetric tower for the Friedrichs and bridging extensions is §4.2; a general cone condition is not claimed robust. □
So the cone allows the spectrum to evade the positive-bottom mechanism expected from smooth sign holonomy alone, and the form of the evasion is set by the extension: the Friedrichs ground state ϕ0 is bounded but discontinuous at pc, while the bridging ground state at λb is continuous in regularized value but logarithmically divergent there. Each evades the obstruction only through its singular behavior at the cone, where elliptic regularity fails. No realization raises the bottom above zero.
6. Nonconstant Sectors and the First Positive Level
The first positive eigenvalue is governed by the competition between the symmetric zonal mode at 2/R2, common to the Friedrichs and bridging realizations, and the nonconstant sectors, where these realizations agree. We record the bottom of each nonconstant sector and then prove Theorem 1.2.
6.1 The odd (periodic) sectors
The odd transverse modes (Φjo, j=0,1,2,…) produce periodic longitudinal functions. The reduced Sturm-Liouville equation with μj=((2j+1)π/(2W))2 has, in Schrödinger form, an effective potential proportional to sec2(y/R), a symmetric Pöschl-Teller potential.
Proposition 6.1. The function u=∣cos(y/R)∣α with α=(2j+1)πR/(2W) satisfies the reduced Sturm-Liouville equation with eigenvalue λ=α(α+1)/R2.
Proof. Set r=∣cos(y/R)∣, so ∣f∣=r and u=rα. On the smooth locus, R2(r′)2=1−r2 and r′′=−r/R2. Then ∣f∣u′=αrαr′ and
so −(∣f∣u′)′+(μj/∣f∣)u=rα−1[α(α+1)R−2r2−α2R−2+μj]. With μj=α2/R2 the constant terms cancel, leaving α(α+1)R−2∣f∣u. □
Under the substitution x=sin(y/R), ∣cos(y/R)∣α=(1−x2)α/2 is the branch regular at x=1 of the associated Legendre equation of degree and order α; for integer α it is proportional to the sectoral harmonic Pαα, and at α=1 it reduces to Y11 on the covering S2. At both seams ∣cos∣α=1 with vanishing derivative, so periodicity holds for all α, and the spectral parameter runs continuously with W. Near the cone ∣cos(y/R)∣α∼∣δ/R∣α→0; this is the regular Frobenius branch, with finite Dirichlet energy for all α>0; for α≥1 the cone is limit-point and it is the unique self-adjoint mode, while in the wide-band first odd sector (α0<1) it is the branch selected by the Friedrichs extension and by the bridging realization. A ground-state transform makes minimality explicit: writing u=hv with h=∣cos(y/R)∣α, integration by parts gives
so λ=α(α+1)/R2 is the sector ground eigenvalue, unique up to scaling. The apex boundary terms of this transform vanish for every α>0: the weighted flux factors are ∣f∣h2=O(∣δ∣2α+1) and ∣f∣hh′=O(∣δ∣2α), both →0 as δ→0, so even the singular-derivative regular branch of the wide-band first odd sector (0<α0<1) contributes no cone term. Since αj=(2j+1)πR/(2W) is increasing in j, the odd-sector minimum is at j=0:
This is decreasing in W: above 2/R2 for W<πR/2, equal at W=πR/2, and below for W>πR/2.
6.2 The even nonconstant sectors
Proposition 6.2. For each even nonconstant sector, k≥1, the sector ground eigenvalue is αk(αk+1)/R2 with αk=kπR/W, attained by the sign-flipped solution sgn(δ)∣cos(y/R)∣αk. Since αk>1 for all k≥1 and W<πR, every even nonconstant sector lies strictly above 2/R2.
Proof. The even nonconstant modes (Φke, k≥1) produce anti-periodic longitudinal functions. The sector ground state is obtained by a sign flip across the cone,
uk(y)=sgn(δ)∣cos(y/R)∣αk,αk=WkπR,
which is anti-periodic at the seams and continuous at the cone (the sign flip multiplies a vanishing factor), with vanishing weighted flux and no distributional contribution; it lies in every self-adjoint extension's domain, the cone being limit-point in these sectors. On each half, ∣cos(y/R)∣αk is positive and nodeless, so by the Sturm oscillation theorem for the separated half-interval problem (Neumann at the seam, regular Frobenius at the cone) it is the half-interval ground state, with eigenvalue αk(αk+1)/R2. Since αk=kπR/W≥πR/W>1 for all k≥1 and W<πR, every even nonconstant sector lies strictly above 2/R2. The sharp +1 in αk(αk+1) matters: a potential-only bound gives αk2/R2, which fails to clear 2/R2 for αk∈(1,2), whereas αk(αk+1)/R2>2/R2 for all αk>1. □
Sector-bottom divergence. The sector bottoms tend to +∞, which is what gives each realization of Definition 3.5 compact resolvent and discrete spectrum (Proposition 3.7). In the sector with transverse Neumann eigenvalue μ the indicial exponent is α=μR, and the ground-state transforms of §6.1 and §6.2 identify the nonconstant sector bottom as α(α+1)/R2. In the bridging realization the constant sector is bounded below by λb(δ0) (Proposition 4.4), while in the Friedrichs realization it is bounded below by 0; in either case the constant sector is a single summand and does not affect the divergence of the nonconstant sector bottoms. The transverse Neumann eigenvalues μke=(kπ/W)2 and μjo=((2j+1)π/(2W))2 increase without bound in the sector index, so α→∞ and the bottoms α(α+1)/R2→+∞.
6.3 The mode crossing
Proof of Theorem 1.2. By Proposition 3.7 the spectrum of each realization is discrete and reduces over the transverse sectors, so the first positive eigenvalue is the minimum of the first positive sector entries. By §4.2 the constant sector contributes 2/R2 as its first positive value, shared by the Friedrichs extension and, by Proposition 4.4, by every bridging extension with δ0>2R/e. The odd sectors contribute α0(α0+1)/R2 with α0=πR/(2W) (§6.1), and by §6.2 the even nonconstant sectors lie strictly above 2/R2. The function α↦α(α+1) is increasing, and α0 is decreasing in W, so the first positive eigenvalue is min(2/R2,α0(α0+1)/R2): it equals 2/R2 when α0≥1, i.e. W≤πR/2, and α0(α0+1)/R2 when W>πR/2. At W=πR/2 both branches give 2/R2. □
For W>πR/2 the hypothesis δ0>2R/e is sufficient but not sharp: the first positive level is then α0(α0+1)/R2<2/R2, and since G is strictly increasing the deformed constant-sector root clears it exactly when ln(δ0/2R)>G(α0(α0+1)/R2), a threshold strictly below −1. The uniform condition is thus sharp precisely at and below the critical width.
The transition is a crossing between two competing low modes (Figure 3). The zonal branch at 2/R2 is the curvature-set mode of the constant sector, independent of the width; the twisted branch at α0(α0+1)/R2 is the lowest transverse mode, whose cost is set by the width through α0=πR/(2W). For narrow bands the transverse mode is expensive and the first positive level is zonal; as the band widens the twisted mode cheapens and drops below the zonal branch exactly at cone angle π, that is at W=πR/2, where the two branches cross and the first positive level is doubly degenerate.
<img src="https://github.com/dmobius3/mode-identity-theory/blob/main/files/assets/mode-crossing.png" width="70%" alt="The width-driven mode crossing: the width-independent zonal branch crossed by the falling twisted branch at cone angle pi">
Figure 3. The width-driven mode crossing of Theorem 1.2. The zonal mode 2/R2 (solid) is width-independent; the lowest twisted mode α0(α0+1)/R2, α0=πR/(2W) (dashed), falls as the band widens and crosses the zonal branch at cone angle π, i.e. W=πR/2, where the two modes are degenerate. The first positive level is the lower envelope of the two branches.
Corollary 6.3 (Degeneracy at the transition). Let W=πR/2; away from this critical width the first positive eigenvalue is simple.
(i)(Critical width) For the Friedrichs extension and for sector-regular bridging with δ0>2R/e, the first-positive eigenspace is two-dimensional, spanned by ψ1=sin(y/R) and ψ2=∣cos(y/R)∣sin(w/R). On the covering S2, ψ1 restricts from Y10 while ψ2 does not lift to a smooth function (the absolute value is required by equivariance, not a coordinate artifact).
(ii)(The next levels) Nothing further reaches 2/R2: the next entries sit at 6/R2, from the k=1 even bottom, the ℓ=2 entry of the Friedrichs antisymmetric tower, and the second entry of the j=0 odd sector, and at 12/R2, from the ℓ=3 symmetric tower and the j=1 odd bottom. For bridging with δ0>2R/e the next eigenvalue above the two-dimensional eigenspace is instead the deformed antisymmetric root. It lies in (2/R2,6/R2) for every finite such δ0 and increases to 6/R2 as δ0→∞. In that limit the deformed tower climbs back onto the Friedrichs tower, as the renormalized condition degenerates to the Friedrichs condition.
(iii)(Double threshold) At δ0=2R/e the deformed root coincides with the symmetric ℓ=1 value (Proposition 4.4), and the bridging first-positive eigenspace becomes three-dimensional, the additional mode represented by sgn(δ)Q1(sin(y/R)): the Neumann-seam solution at ν=1, pure Q1 since Q1′(0)=0, logarithmically divergent at the cone, antisymmetric in cone parity and distinct from the transverse-odd ψ2. The three modes are mutually orthogonal, and the next entries remain strictly above.
Corollary 6.4 (Sign-changing first positive eigenfunction). For W>πR/2 the representative ∣cos(y/R)∣α0sin(πw/2W) of the first positive eigenfunction changes sign across w=0 (the core loop). The sign change is a fixed parity feature of the odd transverse factor sin(πw/2W), not a movable node. The holonomy enters through the Möbius pairing of §3.4, which couples this parity class to periodic longitudinal behavior, and decisively through the absence of a globally positive representative recorded below. For W<πR/2 the representative sin(y/R) is positive on the interior but vanishes at the seam, where the Möbius identification imposes the sign reversal. Because L is nontrivial, no section admits a globally positive representative, so the Perron-Frobenius nodeless-ground argument does not apply.
7. Physical Interpretation and Limiting Regimes
Ground state versus first positive level. This model separates two spectral effects. The first positive level is the rigid one: in the narrow regime it equals 2/R2 for the Friedrichs extension and for bridging with δ0>2R/e, with the width-driven mode crossing at W=πR/2. The bottom of the spectrum, by contrast, is extension-dependent: every nonnegative extension has bottom 0, while the bridging family has bottom λb(δ0)<0, so the gap above the ground state moves with δ0 even where the first positive level does not. Anti-periodicity does not force a positive spectral bottom (Lemma 3.8). The model thus separates three mechanisms often entangled in singular quantum systems: the topology imposes the Z2 sign holonomy, the conic defect carries the self-adjoint-extension parameter, and constant curvature makes the mode competition exactly solvable.
Sign holonomy and nodal structure. The anti-periodicity ψ(πR,−w)=−ψ(0,w) is a real Aharonov-Bohm-type sign holonomy: a wavefunction returns to minus itself around the core loop, and the anti-periodic half-integer longitudinal quantization of the even transverse sectors, the constant sector included, is its spectral signature. The nodal pattern changes at the crossing. For W>πR/2 the first positive eigenfunction changes sign across the core loop; for W<πR/2 it is positive in the interior and vanishes at the seam, where the twist imposes the sign reversal. On an orientable surface Perron-Frobenius and Courant's nodal domain theorem [CourantHilbert] would give a positive ground eigenfunction, but on M(W) a nowhere-vanishing section would trivialize L. This is the line-bundle analogue of Shigekawa's magnetic spectral-positivity criterion [Shigekawa]; the cone goes further, letting the bottom itself fall to zero or below.
The defect scale. The renormalization length δ0 is the one quantity in the model that the intrinsic geometry leaves free: it is short-distance defect data, not geometry. The Friedrichs extension needs no such scale and is the standard conic choice [Cheeger1979, Cheeger1983]; its spectrum is the Neumann lune spectrum of Proposition 4.2, so it does not encode any additional vertex-matching data from the Möbius identification, and the bottom is the zero mode. At αBP=−1 it is moreover the unique Markovian realization (Theorem 1.13(ii) of [BP]), the bridging extensions being non-Markovian. Together with the generic decoupling of two-dimensional point interactions, this makes Friedrichs the canonical nonnegative choice. A transmitting limit of smoothed cones would be expected only under tuning to a zero-energy resonance. Whether a geometric regularization selects a canonical δ0, for instance as a norm-resolvent limit of smoothed-cone Laplacians [AGHH], remains open. Until then λb is an extension-dependent quantity rather than an intrinsic invariant, and its leading form carries O(δ02/R2) corrections that are not small at moderate δ0.
The smooth comparison. The singular construction is a modeling choice, and it is worth stating what the conic endpoint buys. The round projective plane RP2(R) contains a smooth constant-curvature Möbius band: the tubular neighborhood of half-width W of a closed geodesic. It has the same core length πR and the same Fermi normal form dt2+cos2(t/R)dσ2, t the transverse distance, and it is smooth for every W<πR/2. That band has a boundary of constant geodesic-curvature magnitude tan(W/R)/R and regular Sturm-Liouville endpoints, so its eigenvalues solve transcendental Legendre matching conditions with no closed form. The conic band trades the smooth boundary for geodesic arcs and a single point defect, and the whole spectrum closes in one secular function. The smooth family moreover exists only for W<πR/2, exhausting RP2 minus a point as W→πR/2. The mode crossing of Theorem 1.2 therefore sits exactly at the closing width of the smooth family, and the conic model is what continues the geometry past it. Proposition 4.2 sharpens the comparison: the Friedrichs realization is spectrally an orientable object, a Neumann lune, so the bridging family is where the non-orientable defect physics genuinely lives.
Limiting regimes. The thin-strip limit is already visible in the closed forms, and it clarifies why this model does not converge to the effective dynamics of [KKZ]. As W→0 every nonconstant sector bottom α(α+1)/R2 diverges, the smallest indicial exponent being α0=πR/(2W). On any fixed spectral window the spectrum therefore reduces to the W-independent constant sector, the zonal problem of §4: for the Friedrichs extension the combined towers ℓ(ℓ+1)/R2, ℓ≥0, and for bridging the symmetric tower together with the deformed antisymmetric roots and the bound state λb(δ0). The limit is thus the zonal Legendre problem rather than a Mathieu-type effective operator as in [KKZ]: their effective potential is generated by the geodesic curvature of a non-geodesic core curve, while our core loop is a geodesic and the degeneration is concentrated in the cone at every width. What the two models share is the parity bookkeeping of the Möbius holonomy, visible in [KKZ] as their m+n odd selection rule. The two thin limits lie on opposite branches of it, carried by different structures: [KKZ] carry the twist geometrically, through the t↦−t boundary identification acting on scalar functions, so their surviving Dirichlet mode is longitudinally periodic, while we carry it as the sign holonomy of the orientation bundle, so our Neumann constant mode is anti-periodic (§3.4). Natural continuations within the same self-adjoint framework include Robin conditions at the regular boundary arcs and the wider family of Lagrangian cone-trace conditions of §3.5.
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