Gromov boundary of the Grand Arc graph
Pith reviewed 2026-07-02 02:59 UTC · model grok-4.3
The pith
Geodesic laminations form a dense subset of the Gromov boundary of the grand arc graph on an infinite-type surface.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
We describe a dense subset of the Gromov boundary of the grand arc graph of an infinite-type surface as a space of geodesic laminations, analogous to Klarreich's description of the Gromov boundary of the curve complex. After showing that the grand arc graph satisfies a bounded geodesic image theorem, we also prove that the boundary is not compact.
What carries the argument
The grand arc graph on an infinite-type surface, with its Gromov boundary partially identified with geodesic laminations via the bounded geodesic image theorem.
If this is right
- The Gromov boundary of the grand arc graph is not compact.
- The bounded geodesic image theorem holds for the grand arc graph.
- Geodesic laminations serve as a dense set of points in the boundary.
- Results known for the curve complex boundary have direct analogues for the grand arc graph.
Where Pith is reading between the lines
- The same lamination description may apply to other arc or curve graphs on infinite-type surfaces once a bounded geodesic image theorem is verified.
- Non-compactness of the boundary could constrain the dynamics of the mapping class group action on the graph.
- The identification supplies a candidate for studying quasi-isometric rigidity questions for these graphs.
Load-bearing premise
The grand arc graph satisfies a bounded geodesic image theorem.
What would settle it
A sequence of grand arcs whose geodesics in the graph fail to remain within bounded distance of a fixed geodesic lamination while approaching a boundary point would falsify the dense-subset identification.
Figures
read the original abstract
We describe a dense subset of the Gromov boundary of the grand arc graph of an infinite-type surface as a space of geodesic laminations, analogous to Klarreich's description of the Gromov boundary of the curve complex. After showing that the grand arc graph satisfies a bounded geodesic image theorem, we also prove that the boundary is not compact.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper claims to describe a dense subset of the Gromov boundary of the grand arc graph of an infinite-type surface as a space of geodesic laminations (analogous to Klarreich's theorem for the curve complex), after establishing that the grand arc graph satisfies a bounded geodesic image theorem; it further proves that this boundary is not compact.
Significance. If the results hold, the work extends boundary descriptions from finite-type to infinite-type surfaces via standard hyperbolic geometry techniques for arc graphs, and the non-compactness result distinguishes the infinite-type case. The strategy of proving a bounded geodesic image theorem to identify the boundary with laminations follows established methods in the field.
minor comments (1)
- [Abstract] The abstract states the main theorems clearly but supplies no proof outlines or verification steps; the full manuscript should include explicit references to the sections containing the bounded geodesic image theorem proof and the boundary identification argument to facilitate checking.
Simulated Author's Rebuttal
We thank the referee for their positive assessment of our work and for recommending minor revision. The referee's summary accurately captures the main results of the paper. No specific major comments were raised in the report.
Circularity Check
No significant circularity; derivation relies on independent proof of BGIT and external analogy
full rationale
The paper explicitly states it proves the bounded geodesic image theorem for the grand arc graph before using it to identify a dense subset of the Gromov boundary with geodesic laminations, mirroring Klarreich's external result on the curve complex. No self-citations are load-bearing, no parameters are fitted and renamed as predictions, and no ansatz or uniqueness theorem is smuggled in via prior author work. The central claim is derived from a stated internal proof plus standard techniques, making the chain self-contained against external benchmarks.
Axiom & Free-Parameter Ledger
Reference graph
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