Percolation in the three-dimensional Ising model

Jinhong Zhu; Sheng Fang; Tao Chen; Youjin Deng; Zhiyi Li

arxiv: 2604.05772 · v1 · submitted 2026-04-07 · ❄️ cond-mat.stat-mech

Percolation in the three-dimensional Ising model

Jinhong Zhu , Tao Chen , Zhiyi Li , Sheng Fang , Youjin Deng This is my paper

Pith reviewed 2026-05-10 18:59 UTC · model grok-4.3

classification ❄️ cond-mat.stat-mech

keywords Ising modelpercolationcritical phenomenageometric clustersMonte Carlo simulationuniversality classthree dimensions

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The pith

The three-dimensional Ising model at criticality shows only a single percolation transition for geometric spin clusters.

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

Geometric representations of the Ising model allow study of percolation by occupying bonds between parallel spins with probability p. In two dimensions, critical configurations display two consecutive percolation transitions as p increases. Monte Carlo simulations demonstrate that this double transition disappears in three dimensions, leaving only one transition. The same single-transition behavior appears in the Ising model on the complete graph. Percolation on a two-dimensional layer within the three-dimensional system shows scaling exponents that indicate a new universality class influenced by correlations in the third dimension.

Core claim

The authors establish that critical Ising configurations in three dimensions undergo a single percolation transition of geometric clusters as the bond occupation probability p is varied. This is shown through extensive Monte Carlo simulations on lattices and corroborated by theoretical analysis on the complete graph. In contrast, a two-dimensional layer embedded in the three-dimensional critical Ising model exhibits percolation exponents indicating coupling to out-of-plane correlations and a distinct universality class.

What carries the argument

Geometric spin clusters connected by occupied bonds with probability p on critical Ising spin configurations; this mechanism reveals the percolation behavior and allows measurement of scaling exponents in both the full three-dimensional system and embedded layers.

Load-bearing premise

The finite lattices and Monte Carlo sampling used are large enough and have small enough corrections to reliably detect the presence of only one percolation transition rather than missing a closely spaced second one.

What would settle it

If larger-scale simulations or more precise finite-size scaling analysis revealed two distinct percolation thresholds separated by a small interval in p, that would contradict the single-transition conclusion.

Figures

Figures reproduced from arXiv: 2604.05772 by Jinhong Zhu, Sheng Fang, Tao Chen, Youjin Deng, Zhiyi Li.

**Figure 2.** Figure 2: The phase diagrams for the 3D Ising model with percolation coordination numbers (a) [PITH_FULL_IMAGE:figures/full_fig_p003_2.png] view at source ↗

**Figure 3.** Figure 3: Binder ratio Q b s,m for minority-spin clusters versus K in the 3D bulk Ising model with the bond occupied probability p = 1 for various system sizes L. The FSS analysis gives the estimate Kb c = 0.232 38(9). The contrast between the 2D and 3D phase diagrams naturally raises the question of what happens in still higher dimensions. To address this point, we study the Ising model on the CG, where each site … view at source ↗

**Figure 4.** Figure 4: Illustration of the percolation threshold [PITH_FULL_IMAGE:figures/full_fig_p006_4.png] view at source ↗

**Figure 5.** Figure 5: Plots of O/LyO versus L y1 for the critical SL3D Ising model with zp = 6 at p = pc = 1, with y1 taking the correction exponent shown in Table III. (a) The largest cluster size C1 yielding the fractal dimension yh = 1.892 6(20). (b) The hull length Lhull with the estimated exponent dhull = 1.663(4). (c) The shortest-path distance sp with the estimated exponent dmin = 1.080(10). The upper and lower curves in… view at source ↗

read the original abstract

Geometric representations provide a useful perspective on critical phenomena in the Ising model. In a recent study [Phys. Rev. E 112, 034118 (2025)], we found that the two-dimensional critical Ising model exhibits two consecutive percolation transitions for geometric spin clusters as the bond-occupation probability $p$ between parallel spins increases. Here, through extensive Monte Carlo simulations, we show that this phenomenon does not persist in three dimensions, where we observe only a single percolation transition on critical Ising configurations. Further theoretical analysis of the Ising model on the complete graph also yields the same scenario. In addition, we study percolation on a two-dimensional layer embedded in the three-dimensional critical Ising model. For this layer system, we estimate the red-bond exponent $y_p = 0.426(6)$ and the fractal dimensions of the largest cluster, hull, and shortest path as $d_f = 1.8926(20)$, $d_{\rm hull} = 1.663(4)$, and $d_{\rm min} = 1.080(10)$, respectively. These values indicate a distinct universality class induced by coupling to out-of-plane critical correlations.

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

The paper claims double percolation disappears in 3D Ising but finite-lattice Monte Carlo may not fully exclude a hidden second transition.

read the letter

Here's the quick take on this arXiv paper: the double-percolation thing from 2D critical Ising clusters goes away in three dimensions, leaving just one transition, and they report fresh exponent values for percolation on a 2D layer sitting inside the 3D model. The new part is the 3D finding itself, which flips the 2D result, plus those layer exponents like y_p = 0.426(6) and the fractal dimensions. That suggests coupling to the third dimension creates its own universality class. The paper does a decent job running Monte Carlo simulations on the 3D lattices and cross-checking with a complete-graph calculation that also shows only one transition. The simulations are described as extensive, which is good, and the complete-graph part gives an independent angle that doesn't rely on the lattice data. Where it gets softer is the claim that there's definitely no second transition. The Monte Carlo is on finite lattices, and if the two transitions in 3D are closer together than in 2D, the finite-size effects and scaling corrections could easily mask the second one. The stress-test note points this out, and since the abstract doesn't spell out the lattice sizes or the precise way they checked for only one transition, the numerical support is only moderate. The complete-graph analysis is mean-field and doesn't directly address whether the 3D lattice behaves the same. This work is aimed at people who care about geometric representations of critical phenomena, especially how percolation behaves on Ising clusters in different dimensions or in layered setups. Someone simulating or theorizing about 3D systems with embedded 2D layers would find the exponent numbers useful. I think it deserves peer review. The question is specific and the results are new enough that referees should look at the details, particularly on how solid the single-transition conclusion is.

Referee Report

3 major / 2 minor

Summary. The paper claims that the two consecutive percolation transitions observed for geometric clusters in the 2D critical Ising model do not occur in 3D, where Monte Carlo simulations on finite lattices and a complete-graph analysis both indicate only a single percolation transition as the bond-occupation probability p is varied. It further examines percolation on a 2D layer embedded in the 3D critical Ising model, reporting estimates y_p = 0.426(6), d_f = 1.8926(20), d_hull = 1.663(4), and d_min = 1.080(10) that suggest a distinct universality class arising from coupling to out-of-plane correlations.

Significance. If the single-transition conclusion is robust, the work establishes a clear dimensional crossover in the percolation behavior of Ising geometric clusters and supplies concrete exponent values for the coupled layer system that can be used to test universality-class predictions. The independent complete-graph calculation provides mean-field corroboration without relying on lattice-specific fitting.

major comments (3)

[Monte Carlo results for 3D Ising] Monte Carlo section (results for 3D Ising): The manuscript does not specify the range of lattice sizes L, the number of independent samples per (L,p) point, or the exact observable (e.g., percolation probability crossing, cluster-size susceptibility peak, or wrapping probability) used to locate the transition and to rule out a second, closely spaced transition. Without these details it is impossible to quantify the effective resolution set by finite-size scaling and correlation-length corrections, which directly bears on the central claim that only one transition exists.
[Finite-size scaling analysis] Finite-size scaling analysis: The paper reports that the single-transition scenario is supported by data collapse, but does not show or discuss the quality of collapse when a two-transition ansatz (with a small separation Δp) is fitted; a quantitative comparison of χ² or residual errors between one- and two-transition models would be required to substantiate the exclusion of the second transition.
[Layer-system results] Layer-system exponents: The reported values y_p = 0.426(6), d_f = 1.8926(20), etc., are stated to indicate a new universality class, yet the manuscript does not compare them against existing 2D percolation or Ising-layer exponents with error bars or perform a consistency check against hyperscaling relations that would be expected in the coupled system.

minor comments (2)

[Abstract and references] The abstract cites the 2D precursor as Phys. Rev. E 112, 034118 (2025); the reference list should include the full bibliographic entry once the paper is published.
[Layer-system analysis] Notation for the red-bond exponent y_p is introduced without an explicit definition in terms of the bond-occupation probability derivative; a brief equation would clarify its relation to the standard percolation exponents.

Simulated Author's Rebuttal

3 responses · 0 unresolved

We thank the referee for the careful reading and constructive comments on our manuscript. We address each major comment point by point below, indicating the revisions we will make to improve clarity and rigor.

read point-by-point responses

Referee: Monte Carlo section (results for 3D Ising): The manuscript does not specify the range of lattice sizes L, the number of independent samples per (L,p) point, or the exact observable (e.g., percolation probability crossing, cluster-size susceptibility peak, or wrapping probability) used to locate the transition and to rule out a second, closely spaced transition. Without these details it is impossible to quantify the effective resolution set by finite-size scaling and correlation-length corrections, which directly bears on the central claim that only one transition exists.

Authors: We agree that these methodological details are essential. In the revised manuscript we will add a dedicated paragraph in the Monte Carlo section specifying the range of lattice sizes L, the number of independent samples per (L,p) point, and the precise observables (wrapping probability and largest-cluster fraction) used to locate the transition and to exclude a second, closely spaced transition. This will allow readers to assess the finite-size resolution directly. revision: yes
Referee: Finite-size scaling analysis: The paper reports that the single-transition scenario is supported by data collapse, but does not show or discuss the quality of collapse when a two-transition ansatz (with a small separation Δp) is fitted; a quantitative comparison of χ² or residual errors between one- and two-transition models would be required to substantiate the exclusion of the second transition.

Authors: We will perform and include in the revised manuscript an explicit comparison of data-collapse quality between the single-transition model and a two-transition ansatz with variable small Δp. We will report the resulting χ² values (or equivalent residual measures) for both models to provide a quantitative basis for preferring the single-transition scenario. revision: yes
Referee: Layer-system exponents: The reported values y_p = 0.426(6), d_f = 1.8926(20), etc., are stated to indicate a new universality class, yet the manuscript does not compare them against existing 2D percolation or Ising-layer exponents with error bars or perform a consistency check against hyperscaling relations that would be expected in the coupled system.

Authors: We will add to the revised manuscript a table comparing our measured exponents (with error bars) to those of ordinary 2D percolation and other relevant 2D classes. We will also include a consistency check of the appropriate hyperscaling relations for the embedded layer, discussing any deviations attributable to coupling with the out-of-plane critical correlations. These additions will strengthen the evidence for a distinct universality class. revision: yes

Circularity Check

0 steps flagged

No significant circularity; 3D results from direct Monte Carlo sampling and independent complete-graph analysis

full rationale

The paper's central claims—that only a single percolation transition occurs in 3D critical Ising configurations, unlike the two transitions in 2D—are supported by extensive Monte Carlo simulations on finite lattices and a separate theoretical analysis on the complete graph. These do not reduce by the paper's own equations to fitted parameters or self-referential definitions. The sole self-citation is to the authors' prior 2D work to establish the contrast being tested; this citation is not load-bearing for the 3D observations or the complete-graph result, which stands independently. No predictions are constructed from the target data, no ansatzes are smuggled, and no uniqueness theorems are invoked from self-citations. The estimates of exponents (y_p, d_f, etc.) for the embedded layer are direct numerical outputs from the simulations, not circular redefinitions.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The claims rely on standard Monte Carlo sampling of the Ising model at criticality and percolation cluster analysis; no additional free parameters, ad-hoc axioms, or invented entities are introduced beyond the conventional lattice Ising Hamiltonian and geometric cluster definition.

axioms (1)

domain assumption The three-dimensional Ising model on a cubic lattice with nearest-neighbor ferromagnetic interactions exhibits a continuous phase transition at a known critical temperature.
Invoked when sampling configurations at criticality.

pith-pipeline@v0.9.0 · 5511 in / 1436 out tokens · 59224 ms · 2026-05-10T18:59:44.925067+00:00 · methodology

discussion (0)

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ECHOES: this paper passage has the same mathematical shape or conceptual pattern as the Recognition theorem, but is not a direct formal dependency.

through extensive Monte Carlo simulations, we show that this phenomenon does not persist in three dimensions, where we observe only a single percolation transition on critical Ising configurations

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Reference graph

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The analysis parallels that used for the bulk model, and the resulting phase diagrams are shown in Fig

Phase diagram Here, we examine the phase diagram for the layer sys- tem. The analysis parallels that used for the bulk model, and the resulting phase diagrams are shown in Fig. 2. We begin withz p = 4, where the percolation bonds are restricted to nearest neighbors. In the low-temperature region (K > K c), the system crosses from the DO phase to the MP ph...

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Critical exponents We now turn to the critical behavior near the fixed point (K c, pc). Since no percolation transition occurs in the physical intervalp≤1 alongK=K c forz p = 4, we focus onz p = 6. The self-matching property is espe- cially useful here: it fixes the threshold exactly atp c = 1 and impliesP bh = 0 at criticality [22]. These exact con- stra...

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Ising, Beitrag zur theorie des ferromagnetismus, Z

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work page 1925

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Duminil-Copin, 100 years of the (critical) ising model on the hypercubic lattice, Proc

H. Duminil-Copin, 100 years of the (critical) ising model on the hypercubic lattice, Proc. Int. Congr. Math.1, 164 (2022)

work page 2022

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Onsager, Crystal Statistics

L. Onsager, Crystal Statistics. I. A Two-Dimensional Model with an Order-Disorder Transition, Phys. Rev.65, 117 (1944)

work page 1944

[6] [6]

Aizenman, Geometric analysis ofφ4 fields and ising models

M. Aizenman, Geometric analysis ofφ4 fields and ising models. parts i and ii, Commun. Math. Phys.86, 1 (1982)

work page 1982

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R. J. Baxter,Exactly solved models in statistical mechan- ics(Elsevier, 2016)

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A. M. Ferrenberg, J. Xu, and D. P. Landau, Push- ing the limits of monte carlo simulations for the three- dimensional ising model, Phys. Rev. E97, 043301 (2018)

work page 2018

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P. Hou, S. Fang, J. Wang, H. Hu, and Y. Deng, Geometric properties of the fortuin-kasteleyn representation of the ising model, Phys. Rev. E99, 042150 (2019)

work page 2019

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Chang, V

C.-H. Chang, V. Dommes, R. S. Erramilli, A. Homrich, P. Kravchuk, A. Liu, M. S. Mitchell, D. Poland, and D. Simmons-Duffin, Bootstrapping the 3d ising stress tensor, J. High Energy Phys.2025(3), 1

work page 2025

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El-Showk, M

S. El-Showk, M. F. Paulos, D. Poland, S. Rychkov, D. Simmons-Duffin, and A. Vichi, Solving the 3d ising model with the conformal bootstrap, Phys. Rev. D86, 025022 (2012)

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[14] [14]

Poland, S

D. Poland, S. Rychkov, and A. Vichi, The conformal bootstrap: Theory, numerical techniques, and applica- tions, Rev. Mod. Phys.91, 015002 (2019)

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W. Zhu, C. Han, E. Huffman, J. S. Hofmann, and Y.- C. He, Uncovering conformal symmetry in the 3d ising transition: State-operator correspondence from a quan- tum fuzzy sphere regularization, Phys. Rev. X13, 021009 (2023)

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Hu, Y.-C

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work page 2023

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S. Fang, Z. Zhou, and Y. Deng, Geometric upper critical dimensions of the ising model, Phys. Rev. E106, 014101 (2022)

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S. Fang, Z. Zhou, and Y. Deng, Geometric scaling behav- iors of the fortuin-kasteleyn ising model in high dimen- sions, Phys. Rev. E107, 044103 (2023)

work page 2023

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T. Chen, J. Zhu, W. Zhong, S. Fang, and Y. Deng, Per- colation in the two-dimensional ising model, Phys. Rev. E112, 034118 (2025)

work page 2025

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Ouyang, Y

Y. Ouyang, Y. Deng, and H. W. Bl¨ ote, Equivalent- neighbor percolation models in two dimensions: Crossover between mean-field and short-range behavior, Phys. Rev. E98, 062101 (2018)

work page 2018

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V. S. Dotsenko, P. Windey, G. Harris, E. Marinari, E. Martinec, and M. Picco, Critical and topological prop- erties of cluster boundaries in the 3d ising model, Phys. Rev. Lett.71, 811 (1993)

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