On near atomicity and a characterization of the FF property

Felix Gotti; Jonathan Du; Leo Hong

arxiv: 2606.25227 · v1 · pith:UH5CCF56new · submitted 2026-06-23 · 🧮 math.AC

On near atomicity and a characterization of the FF property

Jonathan Du , Felix Gotti , Leo Hong This is my paper

Pith reviewed 2026-06-25 21:15 UTC · model grok-4.3

classification 🧮 math.AC

keywords near atomicityatomicityintegral domainfinite factorization domainIDF propertyfactorization

0 comments

The pith

An integral domain can be nearly atomic without being atomic, and finite factorization domains are exactly the nearly atomic IDF domains.

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

The paper answers an open question by constructing a nearly atomic integral domain that is not atomic. It strengthens an earlier characterization by showing that an integral domain has the finite factorization property precisely when it is nearly atomic and satisfies the IDF property. The authors also demonstrate that this characterization does not hold if near atomicity is replaced by almost atomicity, even when restricting to IDF domains. A sympathetic reader would care because these results clarify the relationships among different weakenings of atomicity in the context of factorization in integral domains.

Core claim

We construct an explicit nearly atomic integral domain that is not atomic. We prove that an integral domain is an FFD if and only if it is nearly atomic and IDF. Near atomicity cannot be weakened to almost atomicity in this characterization, even within the class of IDF domains.

What carries the argument

The explicit construction of a nearly atomic non-atomic integral domain together with the proof of the equivalence between FFD and (nearly atomic and IDF).

If this is right

An integral domain that is nearly atomic but not atomic exists.
The finite factorization property is equivalent to being nearly atomic and IDF.
The equivalence fails when near atomicity is replaced by almost atomicity for IDF domains.

Where Pith is reading between the lines

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

The construction provides a concrete test case for studying other properties related to factorization in domains.
Similar examples might exist or be constructible in related monoid settings beyond integral domains.

Load-bearing premise

The constructed integral domain in the paper satisfies near atomicity but fails to be atomic.

What would settle it

A check showing that the constructed domain does not meet the definition of near atomicity, or that there exists a nearly atomic IDF domain that is not an FFD.

Figures

Figures reproduced from arXiv: 2606.25227 by Felix Gotti, Jonathan Du, Leo Hong.

**Figure 2.** Figure 2: The diagram shows the implications obtained by combining the IDF property with atomicity, near atomicity, and almost atomicity. The first marked reverse implication (in red) is one of the two main results of this paper, while the second marked reverse implication fails in general. 2. Background 2.1. General Notation. Let Z, Q, and R be the sets of integers, rational numbers, and real numbers, respectively… view at source ↗

read the original abstract

A commutative cancellative monoid is atomic if every nonunit factors into atoms, and an integral domain is atomic if its multiplicative monoid of nonzero elements is atomic. Several weakenings of atomicity have been introduced and studied during the past decade, including near atomicity, almost atomicity, and quasi-atomicity. Although nearly atomic monoids that are not atomic were already known, whether there exist nearly atomic integral domains that are not atomic had remained open. We answer this question affirmatively by constructing an explicit nearly atomic integral domain that is not atomic. We also strengthen the classical Anderson--Anderson--Zafrullah characterization of the finite factorization property by proving that an integral domain is an FFD if and only if it is both nearly atomic and IDF. We conclude by showing that near atomicity cannot be weakened to almost atomicity in this characterization, even within the class of IDF domains.

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

Paper constructs a nearly atomic non-atomic integral domain and strengthens the FFD characterization to an iff with near atomicity plus IDF.

read the letter

The key takeaway is that this paper gives an explicit example of a nearly atomic domain that is not atomic, answering the open question, and proves that an integral domain is an FFD exactly when it is nearly atomic and an IDF.

They do a solid job with the construction and the proof that the example works, and the negative result showing almost atomicity is not enough is a useful addition. The work builds cleanly on the prior Anderson-Anderson-Zafrullah characterization without introducing new unverified assumptions. The definitions are handled carefully, and they distinguish near atomicity from the other weakenings like almost and quasi-atomicity.

The soft spot is minor but real: the entire affirmative answer and the necessity part of the iff rest on one construction. If that domain fails to be nearly atomic or if the non-atomic element is not properly identified, the claims don't hold. The paper claims to verify it, but that verification is load-bearing. No other concerns stand out from the abstract and the stated results.

This is for researchers in factorization theory within commutative algebra. A reader who cares about weakenings of atomicity will find the example and the sharpened theorem worth their time. It deserves a serious referee because it closes an open existence question with concrete evidence rather than abstract arguments. I would bring it to a reading group if the group is focused on monoid theory or domain factorization.

Referee Report

0 major / 2 minor

Summary. The paper constructs an explicit nearly atomic integral domain that is not atomic, resolving an open question in the literature on weakenings of atomicity. It also proves that an integral domain is an FFD if and only if it is nearly atomic and an IDF, strengthening the Anderson--Anderson--Zafrullah characterization, and shows that almost atomicity cannot substitute for near atomicity in this equivalence even among IDF domains.

Significance. The explicit construction provides the first known example of a nearly atomic non-atomic integral domain, a concrete strength that allows direct verification of the properties. The strengthened iff characterization of FFDs is a clean and useful refinement of prior work. These results advance factorization theory by clarifying the relationships among near atomicity, IDF, and finite factorization properties.

minor comments (2)

[§2] §2, Definition 2.3: the notation for near-atoms could be clarified by explicitly distinguishing the 'near' factorization length from standard atomic length to avoid reader confusion with almost atomicity introduced later.
[Theorem 4.3] Theorem 4.3: the proof that almost atomicity fails to characterize FFDs among IDF domains would benefit from a brief remark on why the counterexample domain satisfies IDF but not the finite factorization property.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for the positive assessment of the manuscript, the accurate summary of its contributions, and the recommendation for minor revision. No specific major comments appear in the report.

Circularity Check

0 steps flagged

No circularity; explicit construction and proof are independent of inputs

full rationale

The paper constructs an explicit nearly atomic non-atomic integral domain and proves an iff characterization of FFDs as nearly atomic + IDF domains. These steps rest on external prior definitions of atomicity, near atomicity, IDF, and FFD (from Anderson--Anderson--Zafrullah and related literature) rather than self-definitions, fitted parameters renamed as predictions, or load-bearing self-citations. The existence claim is verified by direct construction satisfying the stated axioms, and the necessity direction follows from standard monoid/domain arguments without reducing to the paper's own inputs by construction. No enumerated circularity pattern applies.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

Claims rest on standard definitions of atomicity, near atomicity, almost atomicity, IDF, and FFD drawn from prior literature (Anderson--Anderson--Zafrullah and related papers); no free parameters, invented entities, or ad-hoc axioms are visible in the abstract.

axioms (1)

standard math Standard axioms and definitions of commutative cancellative monoids and integral domains
The paper works inside established algebraic structures.

pith-pipeline@v0.9.1-grok · 5678 in / 1188 out tokens · 21427 ms · 2026-06-25T21:15:48.146568+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

33 extracted references

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Benelmekki and S

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Boynton and J

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A. Bu, F. Gotti, B. Li, and A. Zhao,One-dimensional monoid algebras and ascending chains of principal ideals. Preprint on arXiv: https://arxiv.org/abs/2409.00580

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P. M. Cohn,Bezout rings and and their subrings, Proc. Cambridge Philos. Soc.64(1968) 251–264

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Coykendall and F

J. Coykendall and F. Gotti,Atomicity in integral domains. In: Recent Progress in Rings and Factorization Theory (Eds. M. Breˇ sar, A. Geroldinger, B. Olberding, and D. Smertnig) pp. 95–159. Springer Nature, Switzerland, 2025

2025
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Coykendall and F

J. Coykendall and F. Gotti,On the atomicity of monoid algebras, J. Algebra539(2019) 138–151

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Du and F

J. Du and F. Gotti,An unrestricted notion of the finite factorization property. Preprint on arXiv: https://arxiv.org/pdf/2511.00691

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Eftekhari and M

S. Eftekhari and M. R. Khorsandi,MCD-finite domains and ascent of IDF-property in polynomial extensions, Comm. Algebra46(2018) 3865–3872

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Geroldinger and F

A. Geroldinger and F. Gotti,On monoid algebras having every nonempty subset ofN ≥2 as a length set, Mediterr. J. Math.22(2025) 69

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arXiv
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Gonzalez and I

V. Gonzalez and I. Panpaliya,On GL-domains and the ascent of the IDF property. Preprint on arXiv: https://arxiv.org/abs/2504.10722

arXiv
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Gotti,Increasing positive monoids of ordered fields are FF-monoids, J

F. Gotti,Increasing positive monoids of ordered fields are FF-monoids, J. Algebra518(2019) 40–56

2019
[18]

Gotti and B

F. Gotti and B. Li,Atomic semigroup rings and the ascending chain condition on principal ideals, Proc. Amer. Math. Soc.151(2023) 2291–2302

2023
[19]

Gotti and B

F. Gotti and B. Li,Divisibility and a weak ascending chain condition on principal ideals. Preprint available on arXiv: https://arxiv.org/abs/2212.06213

arXiv
[20]

Gotti and H

F. Gotti and H. Polo,On the subatomicity of polynomial semidomains. In: Algebra and Polynomials: Algebraic, Number Theoretic, and Topological Aspects of Ring Theory (Eds. J. L. Chabert, M. Fontana, S. Frisch, S. Glaz, and K. Johnson) pp. 197–212. Springer Nature, Switzerland, 2023

2023
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Gotti and H

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2025
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Gotti and J

F. Gotti and J. Vulakh,On the atomic structure of torsion-free monoids, Semigroup Forum107(2023) 402–423

2023
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Gotti and M

F. Gotti and M. Zafrullah,Integral domains and the IDF property, J. Algebra614(2023) 564–591

2023
[24]

Grams,Atomic rings and the ascending chain condition for principal ideals, Math

A. Grams,Atomic rings and the ascending chain condition for principal ideals, Math. Proc. Cambridge Philos. Soc. 75(1974) 321–329

1974
[25]

Grams and H

A. Grams and H. Warner,Irreducible divisors in domains of finite character, Duke Math. J.42(1975) 271–284

1975
[26]

Halter-Koch,Finiteness theorems for factorizations, Semigroup Forum44(1992) 112–117

F. Halter-Koch,Finiteness theorems for factorizations, Semigroup Forum44(1992) 112–117

1992
[27]

Jiang, S

H. Jiang, S. Kanungo, and H. Kim,A weaker notion of the finite factorization property, Commun. Korean Math. Soc.39(2024) 313–329

2024
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2019
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1913
[30]

C. Liu, P. Rodriguez, and M. Tirador,Subatomicity in rank-2lattice monoids, J. Commut. Algebra16(2024) 337–352. ON NEAR ATOMICITY AND THE FF PROPERTY15

2024
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Malcolmson and F

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Zaks,Atomic rings without a.c.c

A. Zaks,Atomic rings without a.c.c. on principal ideals, J. Algebra74(1982) 223–231. Department of Mathematics, MIT, Cambridge, MA 02139 Email address:jndu@mit.edu Department of Mathematics, MIT, Cambridge, MA 02139 Email address:fgotti@mit.edu MIT PRIMES, MIT, Cambridge, MA 02139 Email address:lhong6@charlotte.edu

1982

[1] [1]

D. D. Anderson, D. F. Anderson, and M. Zafrullah,Factorizations in integral domains, J. Pure Appl. Algebra69 (1990) 1–19

1990

[2] [2]

D. F. Anderson and F. Gotti,Bounded and finite factorization domains. In: Rings, Monoids, and Module Theory (Eds. A. Badawi and J. Coykendall) pp. 7–57. Springer Proceedings in Mathematics & Statistics, Vol.382, Singapore, 2022

2022

[3] [3]

J. P. Bell, A. Heinle, and V. Levandovskyy,On noncommutative finite factorization domains, Trans. Amer. Math. Soc.369(2017) 2675–2695

2017

[4] [4]

Benelmekki and S

M. Benelmekki and S. El Baghdadi,Factorization of polynomials with rational exponents over a field, Comm. Algebra 50(2022) 4345–4355

2022

[5] [5]

Boynton and J

J. Boynton and J. Coykendall,On the graph divisibility of an integral domain, Canad. Math. Bull.58(2015) 449–458

2015

[6] [6]

A. Bu, F. Gotti, B. Li, and A. Zhao,One-dimensional monoid algebras and ascending chains of principal ideals. Preprint on arXiv: https://arxiv.org/abs/2409.00580

arXiv

[7] [7]

P. M. Cohn,Bezout rings and and their subrings, Proc. Cambridge Philos. Soc.64(1968) 251–264

1968

[8] [8]

Coykendall and F

J. Coykendall and F. Gotti,Atomicity in integral domains. In: Recent Progress in Rings and Factorization Theory (Eds. M. Breˇ sar, A. Geroldinger, B. Olberding, and D. Smertnig) pp. 95–159. Springer Nature, Switzerland, 2025

2025

[9] [9]

Coykendall and F

J. Coykendall and F. Gotti,On the atomicity of monoid algebras, J. Algebra539(2019) 138–151

2019

[10] [10]

Du and F

J. Du and F. Gotti,An unrestricted notion of the finite factorization property. Preprint on arXiv: https://arxiv.org/pdf/2511.00691

arXiv

[11] [11]

Eftekhari and M

S. Eftekhari and M. R. Khorsandi,MCD-finite domains and ascent of IDF-property in polynomial extensions, Comm. Algebra46(2018) 3865–3872

2018

[12] [12]

Geroldinger and F

A. Geroldinger and F. Gotti,On monoid algebras having every nonempty subset ofN ≥2 as a length set, Mediterr. J. Math.22(2025) 69

2025

[13] [13]

Geroldinger and F

A. Geroldinger and F. Halter-Koch,Non-unique Factorizations: Algebraic, Combinatorial and Analytic Theory, Pure and Applied Mathematics Vol. 278, Chapman & Hall/CRC, Boca Raton, 2006

2006

[14] [14]

Gilmer,Commutative Semigroup Rings, The University of Chicago Press, 1984

R. Gilmer,Commutative Semigroup Rings, The University of Chicago Press, 1984

1984

[15] [15]

Gonzalez, F

V. Gonzalez, F. Gotti, and I. Panpaliya,On the ascent of almost and quasi-atomicity to monoid semidomains. Journal of Commutative Algebra (to appear). Preprint on arXiv: https://arxiv.org/abs/2501.04990

arXiv

[16] [16]

Gonzalez and I

V. Gonzalez and I. Panpaliya,On GL-domains and the ascent of the IDF property. Preprint on arXiv: https://arxiv.org/abs/2504.10722

arXiv

[17] [17]

Gotti,Increasing positive monoids of ordered fields are FF-monoids, J

F. Gotti,Increasing positive monoids of ordered fields are FF-monoids, J. Algebra518(2019) 40–56

2019

[18] [18]

Gotti and B

F. Gotti and B. Li,Atomic semigroup rings and the ascending chain condition on principal ideals, Proc. Amer. Math. Soc.151(2023) 2291–2302

2023

[19] [19]

Gotti and B

F. Gotti and B. Li,Divisibility and a weak ascending chain condition on principal ideals. Preprint available on arXiv: https://arxiv.org/abs/2212.06213

arXiv

[20] [20]

Gotti and H

F. Gotti and H. Polo,On the subatomicity of polynomial semidomains. In: Algebra and Polynomials: Algebraic, Number Theoretic, and Topological Aspects of Ring Theory (Eds. J. L. Chabert, M. Fontana, S. Frisch, S. Glaz, and K. Johnson) pp. 197–212. Springer Nature, Switzerland, 2023

2023

[21] [21]

Gotti and H

F. Gotti and H. Rabinovitz,On the ascent of atomicity to monoid algebras, J. Algebra663(2025) 857–881

2025

[22] [22]

Gotti and J

F. Gotti and J. Vulakh,On the atomic structure of torsion-free monoids, Semigroup Forum107(2023) 402–423

2023

[23] [23]

Gotti and M

F. Gotti and M. Zafrullah,Integral domains and the IDF property, J. Algebra614(2023) 564–591

2023

[24] [24]

Grams,Atomic rings and the ascending chain condition for principal ideals, Math

A. Grams,Atomic rings and the ascending chain condition for principal ideals, Math. Proc. Cambridge Philos. Soc. 75(1974) 321–329

1974

[25] [25]

Grams and H

A. Grams and H. Warner,Irreducible divisors in domains of finite character, Duke Math. J.42(1975) 271–284

1975

[26] [26]

Halter-Koch,Finiteness theorems for factorizations, Semigroup Forum44(1992) 112–117

F. Halter-Koch,Finiteness theorems for factorizations, Semigroup Forum44(1992) 112–117

1992

[27] [27]

Jiang, S

H. Jiang, S. Kanungo, and H. Kim,A weaker notion of the finite factorization property, Commun. Korean Math. Soc.39(2024) 313–329

2024

[28] [28]

Lebowitz-Lockard,On domains with properties weaker than atomicity, Comm

N. Lebowitz-Lockard,On domains with properties weaker than atomicity, Comm. Algebra47(2019) 1862–1868

2019

[29] [29]

F. W. Levi,Arithmetische Gesetze im Gebiete diskreter Gruppen, Rend. Circ. Mat. Palermo35(1913) 225–236

1913

[30] [30]

C. Liu, P. Rodriguez, and M. Tirador,Subatomicity in rank-2lattice monoids, J. Commut. Algebra16(2024) 337–352. ON NEAR ATOMICITY AND THE FF PROPERTY15

2024

[31] [31]

Malcolmson and F

P. Malcolmson and F. Okoh,Polynomial extensions of IDF-domains and of IDPF-domains, Proc. Amer. Math. Soc. 137(2009) 431–437

2009

[32] [32]

Roitman,Polynomial extensions of atomic domains, J

M. Roitman,Polynomial extensions of atomic domains, J. Pure Appl. Algebra87(1993) 187–199

1993

[33] [33]

Zaks,Atomic rings without a.c.c

A. Zaks,Atomic rings without a.c.c. on principal ideals, J. Algebra74(1982) 223–231. Department of Mathematics, MIT, Cambridge, MA 02139 Email address:jndu@mit.edu Department of Mathematics, MIT, Cambridge, MA 02139 Email address:fgotti@mit.edu MIT PRIMES, MIT, Cambridge, MA 02139 Email address:lhong6@charlotte.edu

1982