Irreducibility criterion for certain trinomials
Pith reviewed 2026-05-25 00:35 UTC · model grok-4.3
The pith
Trinomials x^n + ε1 x + p^k ε2 are irreducible when the middle exponent equals 1.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
The authors show that the polynomials x^n + ε1 x + p^k ε2 with m=1 are irreducible. They also provide the cyclotomic factors and reducibility criterion for trinomials of the form x^n + ε1 x^m + ε2 where εi ∈ {-1, +1}. This corrects a few of the existing results of W. Ljunggren.
What carries the argument
Application of Eisenstein's criterion or reduction modulo p to establish that the trinomial with middle exponent m=1 does not factor nontrivially.
If this is right
- These trinomials generate irreducible extensions of degree n over the rationals.
- The cyclotomic factors give the explicit factorization when the constant term has coefficient ±1.
- Reducibility of unit-coefficient trinomials is decided by the supplied criterion.
- Some earlier classifications of reducible cases by Ljunggren must be revised.
Where Pith is reading between the lines
- The irreducibility may extend to other fixed small values of m if the prime-power term dominates the constant term sufficiently.
- Direct computation for small n and various p could provide independent verification of the general statement.
- Such irreducible trinomials could be used to construct number fields whose ring of integers has prescribed properties.
Load-bearing premise
That the exponents satisfy n > m = 1 and that standard Eisenstein or reduction-modulo-p arguments apply without additional hidden conditions on n and k.
What would settle it
An explicit counterexample consisting of a prime p, integer k, signs ε1 and ε2, and n > 1 such that x^n + ε1 x + p^k ε2 factors into lower-degree non-constant integer polynomials.
read the original abstract
In this article we study the irreducibility of polynomials of the form $x^n+\epsilon_1 x^m+p^k\epsilon_2$, $p$ being a prime number. We will show that they are irreducible for $m=1$. We have also provided the cyclotomic factors and reducibility criterion for trinomials of the form $x^n+\epsilon_1x^m+\epsilon_2$, where $\epsilon_i\in \{\, -1,+1\,\}$. This corrects few of the existing results of W. Ljuggren's on $x^n+\epsilon_1x^m+\epsilon_2$.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper studies irreducibility over Q of trinomials of the form x^n + ε1 x^m + p^k ε2 (p prime) and claims to prove they are irreducible when m=1 (n > m). It also gives cyclotomic factors and a reducibility criterion for the case without the p^k term, correcting some results of Ljunggren on x^n + ε1 x^m + ε2.
Significance. A correct proof of the m=1 case would supply a useful explicit irreducibility criterion for a family of trinomials. The manuscript supplies no derivations, error bounds, or lemmas in the abstract, and the central claim is refuted by a counterexample, so the significance is null.
major comments (1)
- Abstract: the claim that x^n + ε1 x^m + p^k ε2 is irreducible for m=1 (n>m, p prime, k≥1, εi=±1) is false. The instance n=3, m=1, p=2, k=1, ε1=ε2=1 yields x^3 + x + 2, which has rational root −1 and factors as (x+1)(x^2 − x + 2) over Q. The reduction-modulo-p argument yields x(x^{n−1} + ε1) mod p and supplies no obstruction; Eisenstein does not apply because the linear coefficient is ±1. Any proof omitting further restrictions on n, k, or p therefore cannot hold.
Simulated Author's Rebuttal
We thank the referee for the careful review and for providing a concrete counterexample that directly addresses our abstract claim. We acknowledge the error and will revise the manuscript accordingly.
read point-by-point responses
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Referee: Abstract: the claim that x^n + ε1 x^m + p^k ε2 is irreducible for m=1 (n>m, p prime, k≥1, εi=±1) is false. The instance n=3, m=1, p=2, k=1, ε1=ε2=1 yields x^3 + x + 2, which has rational root −1 and factors as (x+1)(x^2 − x + 2) over Q. The reduction-modulo-p argument yields x(x^{n−1} + ε1) mod p and supplies no obstruction; Eisenstein does not apply because the linear coefficient is ±1. Any proof omitting further restrictions on n, k, or p therefore cannot hold.
Authors: We agree with the referee that the stated claim is incorrect. The polynomial x^3 + x + 2 is indeed reducible over Q, as verified by the rational root -1 and the explicit factorization. Our manuscript asserted irreducibility for the m=1 case without additional restrictions on n, k, or p, which does not hold in general. We will revise the abstract and remove or qualify the claim of irreducibility for m=1. The sections on cyclotomic factors and the corrected reducibility criteria for x^n + ε1 x^m + ε2 (without the p^k term) are unaffected by this issue. revision: yes
Circularity Check
No circularity detected; derivation self-contained
full rationale
The abstract states a direct claim of irreducibility for m=1 using standard criteria (Eisenstein, reduction mod p) on the given trinomial form, with a correction to external prior results of Ljunggren. No self-definitional equations, fitted parameters renamed as predictions, or load-bearing self-citations appear. The central result does not reduce to its inputs by construction and stands as an independent mathematical argument against external benchmarks.
Axiom & Free-Parameter Ledger
axioms (2)
- standard math Irreducibility over Q is equivalent to irreducibility over Z for monic polynomials (Gauss's lemma).
- standard math Cyclotomic polynomials are irreducible over Q.
discussion (0)
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