In number theory, the Green–Tao theorem, proved by Ben Green and Terence Tao in 2004, states that the sequence of prime numbers contains arbitrarily long arithmetic progressions. In other words, for every natural number , there exist arithmetic progressions of primes with terms. The proof is an extension of Szemerédi's theorem. The problem can be traced back to investigations of Lagrange and Waring from around 1770.[1]

Statement

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Let   denote the number of primes less than or equal to  . If   is a subset of the prime numbers such that

 

then for all positive integers  , the set   contains infinitely many arithmetic progressions of length  . In particular, the entire set of prime numbers contains arbitrarily long arithmetic progressions.

In their later work on the generalized Hardy–Littlewood conjecture, Green and Tao stated and conditionally proved the asymptotic formula

 

for the number of k tuples of primes   in arithmetic progression.[2] Here,   is the constant

 

The result was made unconditional by Green–Tao[3] and Green–Tao–Ziegler.[4]

Overview of the proof

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Green and Tao's proof has three main components:

  1. Szemerédi's theorem, which asserts that subsets of the integers with positive upper density have arbitrarily long arithmetic progressions. It does not a priori apply to the primes because the primes have density zero in the integers.
  2. A transference principle that extends Szemerédi's theorem to subsets of the integers which are pseudorandom in a suitable sense. Such a result is now called a relative Szemerédi theorem.
  3. A pseudorandom subset of the integers containing the primes as a dense subset. To construct this set, Green and Tao used ideas from Goldston, Pintz, and Yıldırım's work on prime gaps.[5] Once the pseudorandomness of the set is established, the transference principle may be applied, completing the proof.

Numerous simplifications to the argument in the original paper[1] have been found. Conlon, Fox & Zhao (2014) provide a modern exposition of the proof.

Numerical work

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The proof of the Green–Tao theorem does not show how to find the arithmetic progressions of primes; it merely proves they exist. There has been separate computational work to find large arithmetic progressions in the primes.

The Green–Tao paper states 'At the time of writing the longest known arithmetic progression of primes is of length 23, and was found in 2004 by Markus Frind, Paul Underwood, and Paul Jobling: 56211383760397 44546738095860 · k; k = 0, 1, . . ., 22.'.

On January 18, 2007, Jarosław Wróblewski found the first known case of 24 primes in arithmetic progression:[6]

468,395,662,504,823 205,619 · 223,092,870 · n, for n = 0 to 23.

The constant 223,092,870 here is the product of the prime numbers up to 23, more compactly written 23# in primorial notation.

On May 17, 2008, Wróblewski and Raanan Chermoni found the first known case of 25 primes:

6,171,054,912,832,631 366,384 · 23# · n, for n = 0 to 24.

On April 12, 2010, Benoît Perichon with software by Wróblewski and Geoff Reynolds in a distributed PrimeGrid project found the first known case of 26 primes (sequence A204189 in the OEIS):

43,142,746,595,714,191 23,681,770 · 23# · n, for n = 0 to 25.

In September 2019 Rob Gahan and PrimeGrid found the first known case of 27 primes (sequence A327760 in the OEIS):

224,584,605,939,537,911 81,292,139 · 23# · n, for n = 0 to 26.

Extensions and generalizations

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Many of the extensions of Szemerédi's theorem hold for the primes as well.

Independently, Tao and Ziegler[7] and Cook, Magyar, and Titichetrakun[8][9] derived a multidimensional generalization of the Green–Tao theorem. The Tao–Ziegler proof was also simplified by Fox and Zhao.[10]

In 2006, Tao and Ziegler extended the Green–Tao theorem to cover polynomial progressions.[11][12] More precisely, given any integer-valued polynomials   in one unknown   all with constant term 0, there are infinitely many integers   such that  , xare simultaneously prime. The special case when the polynomials are   implies the previous result that there arithmetic progressions of primes of length  .

Tao proved an analogue of the Green–Tao theorem for the Gaussian primes.[13]

See also

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References

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  1. ^ a b Green, Ben; Tao, Terence (2008). "The primes contain arbitrarily long arithmetic progressions". Annals of Mathematics. 167 (2): 481–547. arXiv:math.NT/0404188. doi:10.4007/annals.2008.167.481. MR 2415379. S2CID 1883951..
  2. ^ Green, Ben; Tao, Terence (2010). "Linear equations in primes". Annals of Mathematics. 171 (3): 1753–1850. arXiv:math/0606088. doi:10.4007/annals.2010.171.1753. MR 2680398. S2CID 119596965.
  3. ^ Green, Ben; Tao, Terence (2012). "The Möbius function is strongly orthogonal to nilsequences". Annals of Mathematics. 175 (2): 541–566. arXiv:0807.1736. doi:10.4007/annals.2012.175.2.3. MR 2877066.
  4. ^ Green, Ben; Tao, Terence; Ziegler, Tamar (2012). "An inverse theorem for the Gowers  -norm". Annals of Mathematics. 172 (2): 1231–1372. arXiv:1009.3998. doi:10.4007/annals.2012.176.2.11. MR 2950773.
  5. ^ Goldston, Daniel A.; Pintz, János; Yıldırım, Cem Y. (2009). "Primes in tuples. I". Annals of Mathematics. 170 (2): 819–862. arXiv:math/0508185. doi:10.4007/annals.2009.170.819. MR 2552109. S2CID 1994756.
  6. ^ Andersen, Jens Kruse. "Primes in Arithmetic Progression Records". Retrieved 2015-06-27.
  7. ^ Tao, Terence; Ziegler, Tamar (2015). "A multi-dimensional Szemerédi theorem for the primes via a correspondence principle". Israel Journal of Mathematics. 207 (1): 203–228. arXiv:1306.2886. doi:10.1007/s11856-015-1157-9. MR 3358045. S2CID 119685169.
  8. ^ Cook, Brian; Magyar, Ákos (2012). "Constellations in  ". International Mathematics Research Notices. 2012 (12): 2794–2816. doi:10.1093/imrn/rnr127. MR 2942710.
  9. ^ Cook, Brian; Magyar, Ákos; Titichetrakun, Tatchai (2018). "A Multidimensional Szemerédi Theorem in the primes via Combinatorics". Annals of Combinatorics. 22 (4): 711–768. arXiv:1306.3025. doi:10.1007/s00026-018-0402-4. S2CID 126417608.
  10. ^ Fox, Jacob; Zhao, Yufei (2015). "A short proof of the multidimensional Szemerédi theorem in the primes". American Journal of Mathematics. 137 (4): 1139–1145. arXiv:1307.4679. doi:10.1353/ajm.2015.0028. MR 3372317. S2CID 17336496.
  11. ^ Tao, Terence; Ziegler, Tamar (2008). "The primes contain arbitrarily long polynomial progressions". Acta Mathematica. 201 (2): 213–305. arXiv:math/0610050. doi:10.1007/s11511-008-0032-5. MR 2461509. S2CID 119138411.
  12. ^ Tao, Terence; Ziegler, Tamar (2013). "Erratum to "The primes contain arbitrarily long polynomial progressions"". Acta Mathematica. 210 (2): 403–404. doi:10.1007/s11511-013-0097-7. MR 3070570.
  13. ^ Tao, Terence (2006). "The Gaussian primes contain arbitrarily shaped constellations". Journal d'Analyse Mathématique. 99 (1): 109–176. arXiv:math/0501314. doi:10.1007/BF02789444. MR 2279549. S2CID 119664036.

Further reading

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