Additive Ramsey theory over Piatetski-Shapiro numbers

Jonathan Chapman; Philippa Holdridge; Sam Chow

arxiv: 2410.14427 · v4 · pith:73LZIFELnew · submitted 2024-10-18 · 🧮 math.NT · math.CO

Additive Ramsey theory over Piatetski-Shapiro numbers

Jonathan Chapman , Sam Chow , Philippa Holdridge This is my paper

Pith reviewed 2026-05-23 18:48 UTC · model grok-4.3

classification 🧮 math.NT math.CO

keywords partition regularityPiatetski-Shapiro numbersadditive Ramsey theorylinear equationsFourier-analytic transferencedensity resultssparse sets

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The pith

Linear equations remain partition regular over Piatetski-Shapiro numbers floor(n^c) below explicit thresholds depending on the number of variables.

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

This paper characterises when linear equations are partition regular when all variables are restricted to the Piatetski-Shapiro numbers, which are the integers closest to n raised to a power c. The thresholds are c less than 12/11 for three variables, 7/6 for four variables, and 2 for five or more variables. A sympathetic reader would care because these sets become sparser as c increases, so the result shows how sparse a set can be while still guaranteeing monochromatic solutions to linear equations. The work also provides quantitative density estimates for the number of solutions and strengthens an existing tool from Fourier analysis for transferring results from dense sets to sparse ones.

Core claim

We characterise partition regularity for linear equations over the Piatetski-Shapiro numbers floor(n^c) when 1 < c < c^dag(s), where s >= 3 is the number of variables. Here c^dag(3) = 12/11 and c^dag(4) = 7/6, while c^dag(s) = 2 for s >= 5. We also establish density results with quantitative bounds. Following recent developments, we update Browning and Prendiville's version of Green's Fourier-analytic transference principle, strengthening its conclusion.

What carries the argument

The strengthened Fourier-analytic transference principle, which allows transferring partition regularity from the integers to the Piatetski-Shapiro numbers.

Load-bearing premise

The strengthened transference principle can be applied in the Piatetski-Shapiro setting to obtain the partition regularity results.

What would settle it

A concrete linear equation in three variables with no solutions in the Piatetski-Shapiro numbers for some c slightly less than 12/11, while solutions exist in the full integers.

read the original abstract

We characterise partition regularity for linear equations over the Piatetski-Shapiro numbers $\lfloor n^c \rfloor$ when $1 < c < c^\dag(s)$, where $s \geqslant 3$ is the number of variables. Here $c^\dag(3) = 12/11$ and $c^\dag(4) = 7/6$, while $c^\dag(s) = 2$ for $s \geqslant 5$. We also establish density results with quantitative bounds. Following recent developments, we take this opportunity to update Browning and Prendiville's version of Green's Fourier-analytic transference principle, strengthening its conclusion.

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.

Referee Report

0 major / 2 minor

Summary. The manuscript characterizes the partition regularity of linear equations in s variables over the Piatetski-Shapiro sequence {⌊n^c⌋} precisely when 1 < c < c^dag(s), with explicit values c^dag(3) = 12/11, c^dag(4) = 7/6 and c^dag(s) = 2 for s ≥ 5. It also supplies quantitative density results and strengthens the conclusion of Browning–Prendiville’s Fourier-analytic transference principle.

Significance. If the strengthened transference principle applies to the Piatetski-Shapiro sequence at the stated thresholds, the work supplies the first explicit characterization of this form for a sparse, non-polynomial set and furnishes a reusable strengthening of the transference tool. The quantitative density bounds are a further concrete contribution.

minor comments (2)

The abstract states the thresholds without indicating how the major/minor-arc estimates are optimized to produce exactly 12/11 and 7/6; a one-sentence pointer to the relevant parameter choice in the proof would improve readability.
Notation for the updated transference principle (e.g., the precise form of the pseudorandomness hypothesis) should be introduced with a displayed equation early in the paper rather than only in the body of the argument.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for the positive assessment and recommendation of minor revision. The report accurately summarizes the main results on the range of c for which linear equations are partition regular over the Piatetski-Shapiro sequence, the explicit thresholds, the density bounds, and the strengthened transference principle.

Circularity Check

0 steps flagged

No circularity: thresholds derived from strengthened transference principle applied to sequence properties

full rationale

The paper updates Browning and Prendiville's Fourier-analytic transference principle (explicitly stated as an update in the abstract) and applies the strengthened version to obtain partition regularity for linear equations over floor(n^c) when c < c^dag(s), with the explicit values c^dag(3)=12/11 and c^dag(4)=7/6 arising from the analysis of major/minor arc estimates or pseudorandomness conditions for the Piatetski-Shapiro sequence. No quoted step reduces a claimed prediction or first-principles result to a fitted input, self-definition, or load-bearing self-citation chain by construction. The derivation is self-contained against the external benchmark of the prior transference principle, which is independent of the present thresholds.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

Abstract-only review supplies no explicit free parameters, axioms, or invented entities; the central claims rest on the applicability of the updated transference principle whose details are not visible.

pith-pipeline@v0.9.0 · 5635 in / 1044 out tokens · 21922 ms · 2026-05-23T18:48:04.966427+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

37 extracted references · 37 canonical work pages

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Chapman, Partition regularity for systems of diagonal equations , Int

J. Chapman, Partition regularity for systems of diagonal equations , Int. Math. Res. Not. 2022, 13272–13316

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Chapman and S

J. Chapman and S. Chow, Arithmetic Ramsey theory over the primes , Proc. Roy. Soc. Edinburgh Sect. A, to appear

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Chapman and S

J. Chapman and S. Chow, Generalised Rado and Roth criteria , Ann. Sc. Norm. Super. Pisa Cl. Sci. (5), to appear

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Y. Filmus, H. Hatami, K. Hosseini, and E. Kelman, Sparse Graph Counting and Kelley–Meka Bounds for Binary Systems . In: 2024 IEEE 65th Annual Symposium on Foundations of Computer Science (FOCS 2024), 1559 –1578, IEEE Computer Society, Los Alamitos, CA, 2024

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Graham, Old and new problems in Ramsey theory

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work page 2005
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B. J. Green and S. Lindqvist, Monochromatic solutions to x + y = z2, Canad. J. Math. 71 (2019), 579–605

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D. R. Heath-Brown, The Pjatecki ˘ ı–˘Sapiro prime number theorem , J. Number Theory 16 (1983), 242–266

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M. J. H. Heule, O. Kullmann, and V. W. Marek, Solving and verifying the Boolean Pythagorean triples problem via cube-and-conquer . In: Theory and Applications of Satisﬁability Testing—SAT 2016, 228–245, Lecture N otes in Comput. Sci. 9710, Springer, Cham, 2016. 20 JONATHAN CHAPMAN, SAM CHOW, AND PHILIP HOLDRIDGE

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Lamb, Maths proof smashes size record , Nature 534 (2016), 17–18

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M. Mirek, Roth’s theorem in Piatetski-Shapiro primes , Rev. Mat. Iberoam. 31 (2015), 617–656

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Piatetski-Shapiro, On the distribution of prime numbers in sequences of the form ⌊f (n)⌋, Math

I. Piatetski-Shapiro, On the distribution of prime numbers in sequences of the form ⌊f (n)⌋, Math. Sbornik 33 (1953), 559–566

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Prendiville, Counting monochromatic solutions to diagonal Diophantine equations, Discrete Anal

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Robert and P

O. Robert and P. Sargos, Three-dimensional exponential sums with monomials , J. Reine Angew. Math. 591 (2006), 1–20

work page 2006
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K. F. Roth, On certain sets of integers , J. London Math. Soc. 28 (1953), 104–109

work page 1953
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Saito and Y

K. Saito and Y. Yoshida, Arithmetic Progressions in the Graphs of Slightly Curved Sequences, J. Integer Seq. 22 (2019), Article 19.2.1

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[34]

Schur, ¨Uber die Kongruenz xm + ym ≡ zm (mod p), Jahresber

I. Schur, ¨Uber die Kongruenz xm + ym ≡ zm (mod p), Jahresber. Deutsch. Math.-Verein. 25 (1916), 114–117

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[35]

Szemer´ edi,On sets of integers containing no k elements in arithmetic pro- gression, Acta Arith

E. Szemer´ edi,On sets of integers containing no k elements in arithmetic pro- gression, Acta Arith. 27 (1975), 199–245

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Varnavides, On certain sets of positive density , J

P. Varnavides, On certain sets of positive density , J. London Math. Soc. 34 (1959), 358–360

work page 1959
[37]

Zhang and R

Q. Zhang and R. Zhang, Roth-type Theorem for High-power System in Piatetski-Shapiro primes , Front. Math. 20 (2025), 67–86. Mathematics Institute, Zeeman Building, University of W ar wick, Coventry CV4 7AL, United Kingdom Email address : Jonathan.Chapman@warwick.ac.uk Mathematics Institute, Zeeman Building, University of W ar wick, Coventry CV4 7AL, Unite...

work page 2025

[1] [1]

Aistleitner, D

C. Aistleitner, D. El-Baz, and M. Munsch, A pair correlation problem, and counting lattice points with the zeta function , Geom. Funct. Anal. 31 (2021), 483–512

work page 2021

[2] [2]

F. A. Behrend, On sets of integers which contain no three terms in arithmeti cal progression, Proc. Nat. Acad. Sci. U. S. A. 32 (1946), 331–332

work page 1946

[3] [3]

T. F. Bloom, Translation invariant equations and the method of Sanders , Bull. Lond. Math. Soc. 44 (2012), 1050–1067

work page 2012

[4] [4]

T. F. Bloom and O. Sisask, An improvement to the Kelley-Meka bounds on three-term arithmetic progressions, arXiv:2309.02353

work page arXiv

[5] [5]

Bourgain, On Λ(p)-subsets of squares , Israel J

J. Bourgain, On Λ(p)-subsets of squares , Israel J. Math. 67 (1989), 291–311

work page 1989

[6] [6]

T. D. Browning and S. M. Prendiville, A transference approach to a Roth-type theorem in the squares , Int. Math. Res. Not. 2017, 2219–2248

work page 2017

[7] [7]

Chapman, Partition regularity for systems of diagonal equations , Int

J. Chapman, Partition regularity for systems of diagonal equations , Int. Math. Res. Not. 2022, 13272–13316

work page 2022

[8] [8]

Chapman and S

J. Chapman and S. Chow, Arithmetic Ramsey theory over the primes , Proc. Roy. Soc. Edinburgh Sect. A, to appear

work page

[9] [9]

Chapman and S

J. Chapman and S. Chow, Generalised Rado and Roth criteria , Ann. Sc. Norm. Super. Pisa Cl. Sci. (5), to appear

work page

[10] [10]

Chow, Roth–Waring–Goldbach, Int

S. Chow, Roth–Waring–Goldbach, Int. Math. Res. Not. 2018, 2341–2374

work page 2018

[11] [11]

S. Chow, S. Lindqvist, and S. Prendiville, Rado’s criterion over squares and higher powers , J. Eur. Math. Soc. 23 (2021), 1925–1997

work page 2021

[12] [12]

Filmus, H

Y. Filmus, H. Hatami, K. Hosseini, and E. Kelman, Sparse Graph Counting and Kelley–Meka Bounds for Binary Systems . In: 2024 IEEE 65th Annual Symposium on Foundations of Computer Science (FOCS 2024), 1559 –1578, IEEE Computer Society, Los Alamitos, CA, 2024

work page 2024

[13] [13]

Frankl, R

P. Frankl, R. L. Graham, and V. R¨ odl, Quantitative Theorems for Regular Systems of Equations , J. Combin. Theory Ser. A 47 (1988), 246–261

work page 1988

[14] [14]

Frantzikinakis, O

N. Frantzikinakis, O. Klurman, and J. Moreira, Partition regularity of Pythagorean pairs, arXiv:2309.10636

work page arXiv

[15] [15]

Graham, Some of my favorite problems in Ramsey theory

R. Graham, Some of my favorite problems in Ramsey theory . In: Combinatorial Number Theory, 229–236, Walter de Gruyter & Co., Berlin, 2007

work page 2007

[16] [16]

Graham, Old and new problems in Ramsey theory

R. Graham, Old and new problems in Ramsey theory . In: Horizons of Combi- natorics, 105–118, Bolyai Soc. Math. Stud. 17, Springer, Berlin, 2008

work page 2008

[17] [17]

B. J. Green, Roth’s theorem in the primes , Ann. of Math. (2) 161 (2005), no. 3, 1609–1636

work page 2005

[18] [18]

B. J. Green and S. Lindqvist, Monochromatic solutions to x + y = z2, Canad. J. Math. 71 (2019), 579–605

work page 2019

[19] [19]

D. R. Heath-Brown, The Pjatecki ˘ ı–˘Sapiro prime number theorem , J. Number Theory 16 (1983), 242–266

work page 1983

[20] [20]

M. J. H. Heule, O. Kullmann, and V. W. Marek, Solving and verifying the Boolean Pythagorean triples problem via cube-and-conquer . In: Theory and Applications of Satisﬁability Testing—SAT 2016, 228–245, Lecture N otes in Comput. Sci. 9710, Springer, Cham, 2016. 20 JONATHAN CHAPMAN, SAM CHOW, AND PHILIP HOLDRIDGE

work page 2016

[21] [21]

Kelley and R

Z. Kelley and R. Meka, Strong Bounds for 3-Progressions , In: 2023 IEEE 64th Annual Symposium on Foundations of Computer Science (FOCS 2023), 933–973, IEEE Computer Society, Los Alamitos, CA, 2023

work page 2023

[22] [22]

Ko´ sciuszko, Counting solutions to invariant equations in dense sets , arXiv:2306.08567

T. Ko´ sciuszko, Counting solutions to invariant equations in dense sets , arXiv:2306.08567

work page arXiv

[23] [23]

Lamb, Maths proof smashes size record , Nature 534 (2016), 17–18

E. Lamb, Maths proof smashes size record , Nature 534 (2016), 17–18

work page 2016

[24] [24]

T. H. Lˆ e, Problems and results on intersective sets . In: Combinatorial and additive number theory—CANT 2011 and 2012, 115–128, Springer P roc. Math. Stat. 101, Springer, New York, 2014

work page 2011

[25] [25]

Mirek, Roth’s theorem in Piatetski-Shapiro primes , Rev

M. Mirek, Roth’s theorem in Piatetski-Shapiro primes , Rev. Mat. Iberoam. 31 (2015), 617–656

work page 2015

[26] [26]

Moreira, Monochromatic sums and products in N, Ann

J. Moreira, Monochromatic sums and products in N, Ann. of Math. (2) 185 (2017), 1069–1090

work page 2017

[27] [27]

P. P. Pach, Monochromatic solutions to x + y = z2 in the interval [N, cN 4], Bull. Lond. Math. Soc. 50 (2018), 1113–1116

work page 2018

[28] [28]

Piatetski-Shapiro, On the distribution of prime numbers in sequences of the form ⌊f (n)⌋, Math

I. Piatetski-Shapiro, On the distribution of prime numbers in sequences of the form ⌊f (n)⌋, Math. Sbornik 33 (1953), 559–566

work page 1953

[29] [29]

Prendiville, Counting monochromatic solutions to diagonal Diophantine equations, Discrete Anal

S. Prendiville, Counting monochromatic solutions to diagonal Diophantine equations, Discrete Anal. (2021), Paper No. 14, 47 pages

work page 2021

[30] [30]

Rado, Studien zur Kombinatorik , Math

R. Rado, Studien zur Kombinatorik , Math. Z. 36 (1933), 424–470

work page 1933

[31] [31]

Robert and P

O. Robert and P. Sargos, Three-dimensional exponential sums with monomials , J. Reine Angew. Math. 591 (2006), 1–20

work page 2006

[32] [32]

K. F. Roth, On certain sets of integers , J. London Math. Soc. 28 (1953), 104–109

work page 1953

[33] [33]

Saito and Y

K. Saito and Y. Yoshida, Arithmetic Progressions in the Graphs of Slightly Curved Sequences, J. Integer Seq. 22 (2019), Article 19.2.1

work page 2019

[34] [34]

Schur, ¨Uber die Kongruenz xm + ym ≡ zm (mod p), Jahresber

I. Schur, ¨Uber die Kongruenz xm + ym ≡ zm (mod p), Jahresber. Deutsch. Math.-Verein. 25 (1916), 114–117

work page 1916

[35] [35]

Szemer´ edi,On sets of integers containing no k elements in arithmetic pro- gression, Acta Arith

E. Szemer´ edi,On sets of integers containing no k elements in arithmetic pro- gression, Acta Arith. 27 (1975), 199–245

work page 1975

[36] [36]

Varnavides, On certain sets of positive density , J

P. Varnavides, On certain sets of positive density , J. London Math. Soc. 34 (1959), 358–360

work page 1959

[37] [37]

Zhang and R

Q. Zhang and R. Zhang, Roth-type Theorem for High-power System in Piatetski-Shapiro primes , Front. Math. 20 (2025), 67–86. Mathematics Institute, Zeeman Building, University of W ar wick, Coventry CV4 7AL, United Kingdom Email address : Jonathan.Chapman@warwick.ac.uk Mathematics Institute, Zeeman Building, University of W ar wick, Coventry CV4 7AL, Unite...

work page 2025