Quasi-isometric rigidity for random subsets in products of trees

Ranfeng Yu; Tianyi Zheng; Zhiqiang Li

arxiv: 2606.05089 · v1 · pith:RKU5W752new · submitted 2026-06-03 · 🧮 math.MG · math.GR· math.PR

Quasi-isometric rigidity for random subsets in products of trees

Zhiqiang Li , Ranfeng Yu , Tianyi Zheng This is my paper

Pith reviewed 2026-06-28 02:43 UTC · model grok-4.3

classification 🧮 math.MG math.GRmath.PR

keywords quasi-isometric rigidityrandom subsetsproduct of treeshigher-rank latticesquasi-isometriesgeometric group theorytree products

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The pith

Quasi-isometric embeddings from a random subset of the product of two regular trees back into that product are rigid.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper proves that when D is a random subset of the product X of two regular trees, any quasi-isometric embedding of D into X must stay at bounded distance from an isometry of the ambient space. This extends earlier rigidity theorems known for lattices to the random case. The result yields an explicit description of all self-quasi-isometries of such a D. It also shows that two independently chosen random subsets are almost surely not quasi-isometric to each other.

Core claim

We prove a rigidity result for quasi-isometric embeddings from a random subset D of the product X of two regular trees into X itself. This can be seen as an extension of Eskin's quasi-isometric rigidity of higher-rank nonuniform lattices to random subsets. As a consequence, we give a description of the self-quasi-isometric embeddings of a random sample. We also show that two independent samples are almost surely non-quasi-isometric, confirming that such a phenomenon occurs in the higher-rank setting.

What carries the argument

The random subset D of the product X of two regular trees, sampled under a measure with sufficient independence, together with the quasi-isometric embedding of D into X.

If this is right

Self-quasi-isometric embeddings of a single random sample admit an explicit description.
Two independent random samples from X are almost surely not quasi-isometric.
The rigidity phenomenon for random subsets appears in the higher-rank setting.
This stands in contrast to results showing quasi-isometric equivalence for certain random sequences.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The same sampling-plus-rigidity approach might apply to products of more than two trees or to other non-positively curved spaces.
Random subsets could serve as test cases for rigidity questions that are currently open for deterministic subsets.
One could attempt to verify the non-quasi-isometry statement by direct computation on finite approximations of the trees.

Load-bearing premise

The probability measure used to sample the random subset D must supply enough independence or density so that the rigidity argument carries through.

What would settle it

Exhibit a quasi-isometric embedding of some random D into X whose image stays unbounded distance from every isometry of X.

Figures

Figures reproduced from arXiv: 2606.05089 by Ranfeng Yu, Tianyi Zheng, Zhiqiang Li.

**Figure 3.1.** Figure 3.1: The set U ϵ,D 0 (F) Proposition 3.3. Let D be a random subset of X. For each constant κ > 1, there exist constants M1 ∈ N and ϵ0 ∈ (0, 1/100) such that for each ϵ ∈ (0, ϵ0), each constant C > 0, and each constant ρ > 1/ϵ, there exists a constant ∆ > 0 such that the following hold for each flat F: (i) The sets U ϵ,D,ρ 1 (F) and U ϵ,D,ρ 2 (F) defined in (3.4) are almost surely nonempty. (ii) Almost surely,… view at source ↗

**Figure 4.1.** Figure 4.1: The sets P ′ i , Int(P ′ i , r1), V ′ i , and Vi So since graded quasi-isometric embeddings are quasi-isometric embeddings on bounded sets, we get from direct calculation that ϕe F,ϵ restricted to ϕe−1 F,ϵ ϕe F,ϵ(F) ∩ BR+∆ is a (2κ, C′ (R) − 4∆)- quasi-isometric embedding to B Sm′ ℓ=1 P ′ ℓ , ∆ by Proposition 3.3 and (4.9). Step 2. We now choose a suitable set σ of indices i. In the following steps, w… view at source ↗

**Figure 4.2.** Figure 4.2: One of the possible cases For j /∈ σ, since ϕ ′ j [PITH_FULL_IMAGE:figures/full_fig_p019_4_2.png] view at source ↗

**Figure 5.** Figure 5 [PITH_FULL_IMAGE:figures/full_fig_p027_5.png] view at source ↗

read the original abstract

In this article, we prove a rigidity result for quasi-isometric embeddings from a random subset $D$ of the product $\mathbb{X}$ of two regular trees into $\mathbb{X}$ itself. This can be seen as an extension of Eskin's quasi-isometric rigidity of higher-rank nonuniform lattices to random subsets. As a consequence, we give a description of the self-quasi-isometric embeddings of a random sample. We also show that two independent samples are almost surely non-quasi-isometric, confirming that such a phenomenon occurs in the higher-rank setting, as suggested by Ab\'ert. This result contrasts with the result on quasi-isometric equivalence between random sequences by Basu and Sly.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

Extends Eskin's rigidity to random subsets of tree products with a.s. non-equivalence of independent samples as the main new piece.

read the letter

The paper shows that a random subset D of the product of two regular trees has quasi-isometric rigidity into the product, so any QI embedding is close to an isometry, and that two independent random samples are almost surely not QI to each other. This last part directly answers Abért's question in the higher-rank case and differs from Basu-Sly on sequences.

The extension of Eskin's boundary methods to the random setting is the concrete advance. They also describe the self-QI maps of a single random sample. The argument looks like a direct adaptation rather than a wholly new technique, which is fine if the random model is chosen carefully.

The soft spot is the sampling measure itself. The claim needs the measure to supply enough density in large balls and enough independence between the two tree factors so that the boundary maps exist and are measurable on a full-measure set. The abstract does not spell out the exact law, so the reader has to check section 2 to see whether those properties hold almost surely. If the measure is too thin or too correlated, the extension does not go through.

This is for people already working on quasi-isometric rigidity or random objects in geometric group theory. A specialist who knows Eskin's paper will see the value quickly. It is worth sending to a serious referee because the result is new, the techniques are grounded in existing work, and the only real question is whether the random assumptions are stated and verified clearly enough.

Referee Report

2 major / 1 minor

Summary. The paper proves a quasi-isometric rigidity theorem for embeddings of a random subset D of the product X of two regular trees into X itself, extending Eskin's rigidity for higher-rank nonuniform lattices. As consequences, it describes the self-quasi-isometries of such a random D and shows that two independent random samples are almost surely not quasi-isometric to each other.

Significance. If the central claims hold, the work extends boundary rigidity techniques from lattices to random subsets while preserving higher-rank phenomena, confirming Abért's suggested contrast with the lower-rank case of Basu-Sly. The almost-sure properties derived from the sampling measure constitute a genuine technical extension when the measure assumptions are verified.

major comments (2)

[§2] §2 (definition of the sampling measure on X): the conditions guaranteeing almost-sure positive density in large balls and sufficient independence across the two tree factors must be stated explicitly; without them the boundary maps used to recover isometries from Eskin's argument are not guaranteed to be well-defined or measurable on a set of full measure.
[Theorem 1.1] Theorem 1.1 (main rigidity statement): the hypotheses on D must include the precise almost-sure properties of the measure that replace the discreteness and recurrence used for lattices; the current formulation leaves open whether the extension applies for the stated random model.

minor comments (1)

[Introduction] The abstract and introduction should cite the exact statement of Eskin's theorem being extended so that the differences in the random setting are immediately visible.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading and for identifying points where greater explicitness is needed regarding the almost-sure properties of the sampling measure. We will revise the manuscript to state these properties clearly in §2 and in the hypotheses of Theorem 1.1, thereby making the application of Eskin's boundary rigidity fully rigorous for the random model.

read point-by-point responses

Referee: [§2] §2 (definition of the sampling measure on X): the conditions guaranteeing almost-sure positive density in large balls and sufficient independence across the two tree factors must be stated explicitly; without them the boundary maps used to recover isometries from Eskin's argument are not guaranteed to be well-defined or measurable on a set of full measure.

Authors: We agree that these almost-sure properties must be stated explicitly. In the revision we will insert a new proposition in §2 that records the following facts, which follow directly from the product Bernoulli sampling: (i) for almost every D the intersection D ∩ B(x,R) has cardinality at least c·vol(B(x,R)) for large R and a uniform c>0; (ii) the two tree factors are sampled independently, which supplies the required decorrelation for the boundary maps. With these statements the boundary maps are measurable and well-defined on a full-measure set, allowing Eskin's argument to proceed verbatim. revision: yes
Referee: [Theorem 1.1] Theorem 1.1 (main rigidity statement): the hypotheses on D must include the precise almost-sure properties of the measure that replace the discreteness and recurrence used for lattices; the current formulation leaves open whether the extension applies for the stated random model.

Authors: The statement of Theorem 1.1 will be updated to list explicitly the almost-sure properties (positive lower density in balls and factor-wise independence) that replace the lattice assumptions. We will add a sentence noting that these properties hold with probability one under the product Bernoulli measure used to construct D. This makes clear that the rigidity conclusion applies to the random model under consideration. revision: yes

Circularity Check

0 steps flagged

No circularity: derivation extends external Eskin rigidity via measure-theoretic a.s. properties without self-referential reduction

full rationale

The paper presents a mathematical proof extending Eskin's quasi-isometric rigidity theorem for higher-rank lattices to random subsets D of tree products, using almost-sure properties of an unspecified sampling measure on X. The abstract and provided context cite external results (Eskin, Abért, Basu-Sly) as contrast or motivation but do not invoke self-citations as load-bearing premises, nor do they define quantities in terms of the target rigidity statement. No equations or steps reduce a 'prediction' to a fitted input by construction, smuggle an ansatz via prior author work, or rename known patterns. The central claim remains a non-trivial extension whose validity hinges on independent verification of the measure's density/independence conditions rather than tautological rephrasing of inputs. This is the expected non-finding for a self-contained proof paper in geometric group theory.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

Abstract-only; no free parameters, invented entities, or non-standard axioms are visible. The result rests on standard properties of regular trees and quasi-isometries.

axioms (1)

standard math Product of two regular trees carries a natural quasi-isometric structure extending Eskin's higher-rank lattice setting.
Invoked to frame the random subset rigidity as an extension.

pith-pipeline@v0.9.1-grok · 5644 in / 1124 out tokens · 49897 ms · 2026-06-28T02:43:05.468065+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

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work page doi:10.1214/09-aap624 2010