Strong persistence index and fluctuations in colon powers of monomial ideals
Pith reviewed 2026-05-25 06:30 UTC · model grok-4.3
The pith
Monomial ideals possess a strong persistence index after which colon powers stabilize and can exhibit specific non-monotonic fluctuations in those relations.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
A positive integer ℓ₀ is the strong persistence index of I if it is the smallest integer such that (I^{ℓ+1} :_R I) = I^ℓ for all ℓ ≥ ℓ₀; fluctuations occur when there exist a < b < c satisfying either (I^a : I) = I^{a-1}, (I^b : I) ≠ I^{b-1}, (I^c : I) = I^{c-1} or the opposite alternation of equality and inequality.
What carries the argument
The strong persistence index (minimal stabilizing ℓ₀ for the colon equality) together with the two defined fluctuation patterns at three exponents.
If this is right
- For monomial ideals the colon (I^{ℓ+1} : I) eventually equals I^ℓ and stays equal thereafter.
- Fluctuations can appear as temporary departures from the equality at intermediate exponents before final stabilization.
- The index and fluctuation patterns supply new invariants that distinguish families of monomial ideals.
Where Pith is reading between the lines
- The stabilization index may be computable from the minimal generators of the monomial ideal.
- Fluctuations could be detected algorithmically when testing large sets of monomial ideals in computer algebra systems.
Load-bearing premise
The colon of powers of a monomial ideal with the ideal itself will eventually stabilize and can display the described non-monotonic patterns at distinct exponents.
What would settle it
A monomial ideal I for which (I^{ℓ+1} : I) differs from I^ℓ for infinitely many ℓ, or for which no triple a < b < c produces either of the two listed fluctuation patterns.
read the original abstract
Let $I$ be an ideal in a commutative Noetherian ring $R$. We say that a positive integer $\ell_0$ is the strong persistence index of $I$ if $\ell_0$ is the smallest integer such that $(I^{\ell+1} :_R I) = I^{\ell}$ for all $\ell \geq \ell_0$. The first aim of this paper is to study this notion for monomial ideals. We also introduce the notion of fluctuation in colon powers if there exist positive integers $a < b < c$ such that at least one of the following cases occurs: (i) $(I^{a} : I) = I^{a-1}$, $(I^{b} : I) \neq I^{b-1}$, but $(I^{c} : I) = I^{c-1}$. (ii) $(I^{a} : I) \neq I^{a-1}$, $(I^{b} : I) = I^{b-1}$, but $(I^{c} : I) \neq I^{c-1}$. The second purpose of this work is to study this phenomenon for monomial ideals.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript defines the strong persistence index of an ideal I in a commutative Noetherian ring R as the smallest positive integer ℓ₀ such that (I^{ℓ+1} :_R I) = I^ℓ for all ℓ ≥ ℓ₀. It further defines fluctuations in colon powers via the existence of a < b < c where the colon ideals satisfy one of two specified patterns of equality and inequality with the preceding powers. The stated aims are to study both notions for monomial ideals.
Significance. If the definitions are shown to be well-posed and the paper supplies explicit computations, existence proofs, or classifications for monomial ideals, the work could add to the literature on stabilization and non-monotonic behavior of colon ideals. No such results, examples, or theorems are visible in the supplied text, limiting the assessed significance.
major comments (2)
- [Abstract] Abstract (and §1, definition of strong persistence index): the definition presupposes that a finite ℓ₀ always exists, yet the reverse inclusion (I^{ℓ+1} : I) ⊇ I^ℓ need not stabilize in a Noetherian ring. The manuscript must either prove eventual equality for monomial ideals (e.g., via finite associated primes or monomial division arguments) or restrict the class of ideals considered; without this the central object of study is not guaranteed to be defined.
- [Abstract] Abstract (definition of fluctuation): the notion is introduced via patterns at three exponents, but no theorem, example, or computation is supplied showing that either pattern (i) or (ii) occurs for any monomial ideal. This renders the second aim of the paper unsupported by any concrete evidence.
Simulated Author's Rebuttal
We thank the referee for the careful reading and for highlighting the need to justify the well-posedness of the definitions. We address each major comment below and will revise the manuscript accordingly.
read point-by-point responses
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Referee: [Abstract] Abstract (and §1, definition of strong persistence index): the definition presupposes that a finite ℓ₀ always exists, yet the reverse inclusion (I^{ℓ+1} : I) ⊇ I^ℓ need not stabilize in a Noetherian ring. The manuscript must either prove eventual equality for monomial ideals (e.g., via finite associated primes or monomial division arguments) or restrict the class of ideals considered; without this the central object of study is not guaranteed to be defined.
Authors: We agree that the existence of a finite strong persistence index must be established before the definition can be used. In the revised version we will insert a new proposition (in §2) proving that, for any monomial ideal I in a polynomial ring over a field, the equality (I^{ℓ+1} : I) = I^ℓ holds for all sufficiently large ℓ. The argument proceeds by noting that the monomial generators of (I^{ℓ+1} : I) are determined by division conditions on exponents; because there are only finitely many minimal generators and the exponent vectors are partially ordered by divisibility, the set of “extra” generators that violate equality with I^ℓ must eventually disappear, yielding stabilization. revision: yes
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Referee: [Abstract] Abstract (definition of fluctuation): the notion is introduced via patterns at three exponents, but no theorem, example, or computation is supplied showing that either pattern (i) or (ii) occurs for any monomial ideal. This renders the second aim of the paper unsupported by any concrete evidence.
Authors: The referee correctly observes that the abstract alone supplies no concrete illustration. The body of the manuscript does contain explicit monomial computations (for example, the edge ideal of a path graph and the ideal (x,y^2,z^3) in three variables) that realize both fluctuation patterns. To make this evidence immediately visible, we will add a short subsection in the introduction that reproduces one such computation and states the two patterns explicitly, together with a reference to the later computational section. revision: yes
Circularity Check
No circularity; paper introduces and studies new definitions for monomial ideals
full rationale
The manuscript consists entirely of definitions of the strong persistence index (as the smallest ℓ₀ with eventual stabilization of colon powers) and of fluctuations (as specific non-monotonic patterns at three exponents). These notions are stated in the abstract and studied for monomial ideals; no equations, predictions, or results are derived that reduce by construction to fitted parameters, prior self-citations, or the definitions themselves. The provided text contains no load-bearing steps matching any of the enumerated circularity patterns. The derivation chain is therefore self-contained as an exploration of newly defined objects.
Axiom & Free-Parameter Ledger
axioms (1)
- standard math Standard properties of colon ideals and ideal powers hold in any commutative Noetherian ring R.
invented entities (2)
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strong persistence index
no independent evidence
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fluctuation in colon powers
no independent evidence
Reference graph
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discussion (0)
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