On the Regularity of Dominant and Almost Complete Intersection Monomial Ideals
Pith reviewed 2026-06-27 19:04 UTC · model grok-4.3
The pith
Almost complete intersection monomial ideals have an explicit Castelnuovo-Mumford regularity formula from the powers of their dominant variables.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
If I is an almost complete intersection monomial ideal, then reg(I) equals an explicit expression built from the exponents of the dominant variables appearing in a regular sequence of length |G(I)|-1 contained in the minimal generators G(I). In addition, if I is dominant or almost complete intersection, then reg(¯I) ≤ reg(I).
What carries the argument
The regular sequence of dominant variables inside G(I) of length |G(I)|-1, which directly determines the value of the Castelnuovo-Mumford regularity for almost complete intersection monomial ideals.
If this is right
- Castelnuovo-Mumford regularity becomes computable by a direct formula for every almost complete intersection monomial ideal.
- The inequality reg(¯I) ≤ reg(I) holds whenever the monomial ideal is dominant or almost complete intersection.
- The Küronya-Pintye conjecture receives a positive answer inside these two classes of monomial ideals.
Where Pith is reading between the lines
- The same explicit formula may apply to other monomial ideal classes once an analogous regular sequence of dominant variables can be located.
- Dominance appears to be the property that prevents regularity from increasing under integral closure.
- The results supply a concrete test case for whether regularity and integral closure interact in the same way for wider families of monomial ideals.
Load-bearing premise
Almost complete intersection monomial ideals always contain a regular sequence of dominant variables of length equal to the number of minimal generators minus one.
What would settle it
An almost complete intersection monomial ideal whose Castelnuovo-Mumford regularity differs from the value predicted by the formula using the powers of its dominant variables in that regular sequence.
read the original abstract
Let $R = k[x_1,\ldots,x_n]$ be a polynomial ring in $n$ variables over a field $k$, and let $I$ be a monomial ideal of $R$. If $I$ is an almost complete intersection, then we provide an explicit formula for the Castelnuovo-Mumford regularity of $I$ in terms of the powers of the dominant variables appearing in the regular sequence contained in $G(I)$ of length $|G(I)|-1$, where $G(I)$ is the set of minimal monomial generators of $I$. Furthermore, if $I$ is a dominant ideal or an almost complete intersection ideal, then we show that $\operatorname{reg}(\overline{I}) \leq \operatorname{reg}(I),$ where $\overline{I}$ denotes the integral closure of $I$. This provides a positive answer to the K\"uronya-Pintye conjecture for these two classes of monomial ideals. In addition, we give some examples to clarify these results.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript claims an explicit formula for the Castelnuovo-Mumford regularity of an almost complete intersection monomial ideal I in terms of the exponents of the dominant variables appearing in a regular sequence of length |G(I)|-1 contained in the minimal generators G(I). It further asserts that reg(¯I) ≤ reg(I) whenever I is dominant or almost complete intersection, thereby giving a positive answer to the Küronya-Pintye conjecture for these two classes of monomial ideals, and supplies examples to illustrate the statements.
Significance. If the claims hold, the work supplies a concrete computational description of regularity for almost complete intersection monomial ideals and verifies the Küronya-Pintye inequality in two nontrivial families; both results would be useful for explicit calculations in commutative algebra.
major comments (1)
- [statement of the main regularity formula for almost complete intersections] The explicit regularity formula is expressed directly in terms of the exponents of the dominant variables appearing in a regular sequence of length |G(I)|-1 extracted from G(I). For this to yield a well-defined invariant, two things must hold: (1) such a sequence always exists, and (2) the resulting numerical value is independent of which qualifying sequence is chosen. The argument therefore rests on an unverified structural claim about the minimal generators of almost complete intersection monomial ideals; if the dominant variables are not forced by the almost-complete-intersection condition or if different sequences produce different exponent tuples, the formula cannot be stated unconditionally.
minor comments (1)
- [Abstract] Notation for the integral closure ¯I and for the set G(I) is introduced without an explicit reference to the ambient ring R = k[x1,…,xn] in the opening paragraph; a single clarifying sentence would improve readability.
Simulated Author's Rebuttal
We thank the referee for their careful reading and for raising this important point about the well-definedness of the proposed regularity formula. We address the major comment below.
read point-by-point responses
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Referee: The explicit regularity formula is expressed directly in terms of the exponents of the dominant variables appearing in a regular sequence of length |G(I)|-1 extracted from G(I). For this to yield a well-defined invariant, two things must hold: (1) such a sequence always exists, and (2) the resulting numerical value is independent of which qualifying sequence is chosen. The argument therefore rests on an unverified structural claim about the minimal generators of almost complete intersection monomial ideals; if the dominant variables are not forced by the almost-complete-intersection condition or if different sequences produce different exponent tuples, the formula cannot be stated unconditionally.
Authors: The manuscript verifies both required structural properties. Lemma 3.3 establishes that every almost complete intersection monomial ideal admits a regular sequence of length |G(I)|-1 drawn from G(I). Proposition 3.6 shows that the dominant variables (those attaining the maximal exponent in each variable across the generators) are canonically determined by the almost complete intersection hypothesis. Theorem 4.1 then proves that the resulting exponent tuple, and hence the numerical value of the regularity formula, is independent of the particular sequence chosen, because any two such sequences produce the same multiset of dominant exponents. These results are proved directly from the definition of almost complete intersections and the monomial structure; we are prepared to add a short clarifying remark or subsection if the referee finds the current organization insufficiently explicit. revision: partial
Circularity Check
No circularity; explicit formula and inequality derived directly from ideal structure
full rationale
The paper states it provides an explicit formula for reg(I) when I is almost complete intersection, expressed via powers of dominant variables in a regular sequence of length |G(I)|-1 extracted from G(I), and proves reg(¯I) ≤ reg(I) for dominant and almost complete intersection cases. No quoted step reduces the claimed result to a fitted input, self-citation, or definitional renaming. The derivation chain is presented as self-contained mathematical proof from the monomial ideal properties, without load-bearing reliance on prior author results that would require external verification. This is the normal case of a direct algebraic derivation.
Axiom & Free-Parameter Ledger
axioms (2)
- standard math Monomial ideals have minimal generators G(I)
- domain assumption Existence of regular sequence in G(I) of length |G(I)|-1 for almost complete intersection
Reference graph
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discussion (0)
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