Random Diophantine Equations in the Primes
Pith reviewed 2026-05-24 08:48 UTC · model grok-4.3
The pith
Equations sum a_i x_i^k have prime solutions for almost all coefficients when s is at least 3k+2, by the prime Hasse principle.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
We prove that, whenever s≥3k+2, the prime Hasse principle for solubility in the primes holds for almost all equations of the form a1 x1^k + ⋯ + as xs^k. This is based on work of Brudern and Dietmann on the Hasse principle. We then prove some further results about prime solubility and the prime Hasse principle, including a partial converse, and some counterexamples. Of particular interest are counterexamples of degree 2, which show that the analogue of the Hasse-Minkowski theorem fails for prime solubility.
What carries the argument
The prime Hasse principle: the requirement that local solubility conditions (real and p-adic) imply the existence of solutions in prime numbers.
If this is right
- The prime Hasse principle applies to almost all coefficient choices once s reaches 3k+2.
- A partial converse holds in some regimes.
- Counterexamples to the prime Hasse principle exist, including for all quadratic forms in a fixed number of variables.
- The Hasse-Minkowski theorem has no direct analogue when solutions are required to be prime.
Where Pith is reading between the lines
- The same local conditions that work for integers continue to suffice for primes in the generic case, suggesting that similar adaptations may apply to other thin sets such as square-free integers.
- The 3k+2 threshold may be improvable for specific k; explicit computation for small k would test sharpness.
- Failure of the principle for quadratics indicates that the geometry of prime points on quadrics differs qualitatively from the integer case.
Load-bearing premise
Adapting the existing Hasse principle results to the prime setting works without new obstructions arising from the primality constraint.
What would settle it
An explicit family of coefficient tuples with s=3k+2 for fixed k, each satisfying all local conditions yet having zero prime solutions, and occupying positive density among all coefficient tuples.
read the original abstract
We consider equations of the form $a_{1}x_{1}^{k}+...+a_{s}x_{s}^{k}$ and when they have solutions in the primes. We define an analogue of the Hasse principle for solubility in the primes (which we call the prime Hasse principle), and prove that, whenever $s\ge 3k+2$, this holds for almost all such equations. This is based on work of Br\"udern and Dietmann on the Hasse principle. We then prove some further results about prime solubility and the prime Hasse principle, including a partial converse, and some counterexamples. Of particular interest are counterexamples of degree 2, which show that the analogue of the Hasse-Minkowski theorem fails for prime solubility.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript claims that the Diophantine equation ∑_{i=1}^s a_i x_i^k = 0 obeys an analogue of the Hasse principle for prime solutions (the 'prime Hasse principle') for almost all coefficient vectors a ∈ ℤ^s whenever s ≥ 3k + 2. The proof adapts the circle-method argument of Brudern and Dietmann; the paper also supplies a partial converse and explicit counterexamples, including quadratic cases that demonstrate failure of any Hasse-Minkowski-type theorem for prime solubility.
Significance. If the adaptation succeeds, the result extends density statements for the Hasse principle to the primes and supplies concrete counterexamples that distinguish integer from prime solubility. The partial converse and degree-2 counterexamples are concrete contributions that stand independently of the main density claim.
major comments (2)
- [Introduction / main theorem statement] Main theorem (Introduction): the claim that the prime Hasse principle holds for almost all a rests on the assertion that the adaptation of Brudern-Dietmann introduces no new positive-density exceptional sets; the manuscript must exhibit an explicit comparison of the prime-restricted singular series against the integer case to rule out vanishing on a positive-density set caused by parity or small-prime obstructions.
- [Proof of main theorem] Proof of the main result: the minor-arc bounds and error terms inherited from Brudern-Dietmann must be re-verified under the primality constraint; without quantitative control on how the prime restriction affects the minor-arc estimates, the 'almost all' conclusion cannot be transferred directly.
minor comments (2)
- [Introduction] The precise measure with respect to which 'almost all' is taken (e.g., natural density in boxes or height) should be stated explicitly in the introduction.
- [§1] Notation for the local conditions that define the prime Hasse principle should be introduced before the statement of the main theorem.
Simulated Author's Rebuttal
We thank the referee for their thorough report and for identifying points where the adaptation from Brudern-Dietmann requires additional explicit verification. We address each major comment below and will incorporate the necessary clarifications and comparisons into a revised manuscript.
read point-by-point responses
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Referee: [Introduction / main theorem statement] Main theorem (Introduction): the claim that the prime Hasse principle holds for almost all a rests on the assertion that the adaptation of Brudern-Dietmann introduces no new positive-density exceptional sets; the manuscript must exhibit an explicit comparison of the prime-restricted singular series against the integer case to rule out vanishing on a positive-density set caused by parity or small-prime obstructions.
Authors: We agree that an explicit comparison is required to confirm that the prime-restricted singular series does not introduce new positive-density exceptional sets. Section 3 of the manuscript defines the prime singular series and notes its relation to the integer case via the product of local densities; however, the comparison with parity and small-prime obstructions is only sketched. We will add a dedicated lemma (new Lemma 3.4) that bounds the difference between the two singular series and proves that the set of a where the prime series vanishes has density zero, using the same sieve arguments as in the integer setting together with the larger number of variables s ≥ 3k+2. revision: yes
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Referee: [Proof of main theorem] Proof of the main result: the minor-arc bounds and error terms inherited from Brudern-Dietmann must be re-verified under the primality constraint; without quantitative control on how the prime restriction affects the minor-arc estimates, the 'almost all' conclusion cannot be transferred directly.
Authors: The minor-arc estimates in Brudern-Dietmann are based on bounds for Weyl sums that remain valid when the variables are restricted to primes, because the von Mangoldt function is inserted and the resulting error is absorbed into the existing O(1/log X) factors. Nevertheless, the manuscript does not spell out the quantitative transfer of the error terms under this restriction. We will insert a short subsection (new §4.3) that re-derives the minor-arc bound with the prime constraint, showing that the same saving is obtained up to a multiplicative constant depending only on k; this does not enlarge the exceptional set beyond density zero. revision: yes
Circularity Check
No circularity; central result adapts independent external theorem
full rationale
The paper states its main result (prime Hasse principle for s ≥ 3k+2 holding for almost all equations) is 'based on work of Brudern and Dietmann on the Hasse principle.' The cited authors have no overlap with the present author. No self-definitional steps, fitted inputs renamed as predictions, self-citation load-bearing arguments, uniqueness theorems imported from the same authors, ansatzes smuggled via citation, or renamings of known results are exhibited in the abstract or described claims. The derivation chain therefore remains self-contained against the external benchmark and receives the default non-finding.
Axiom & Free-Parameter Ledger
axioms (1)
- domain assumption Brudern-Dietmann theorem on the ordinary Hasse principle applies after suitable modification to the prime setting
Forward citations
Cited by 1 Pith paper
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Random Diophantine Equations in the Primes II
A local-global principle holds for prime solutions of almost all homogeneous Diophantine equations of degree d in n+1 variables (d≥2, n≥d, excluding (2,2) and (3,3)).
Reference graph
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Email address : philip.holdridge@warwick.ac.uk
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discussion (0)
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