Goldbach's conjecture: Difference between revisions

From Wikipedia, the free encyclopedia
Jump to navigation Jump to search
← Previous editNext edit →
VisualWikitext
imported>Ianmacm
imported>Ianmacm
rv good faith edit, not really needed, two primes is all that matters. It is obvious that some even numbers do this, eg 6 = 3 +3, 14 = 7 + 7
Line 1: Line 1:
{{Short description|Even integers as sums of two primes}}
{{Short description|Even integers as sums of two primes}}
{{Infobox mathematical statement
{{Infobox mathematical statement
| name = Goldbach's conjecture
| name = Goldbach's conjecture
| image = File:Letter Goldbach-Euler.jpg
| image = File:Letter Goldbach-Euler.jpg
| caption = Letter from Goldbach to Euler dated 07&nbsp;June 1742 ([[Latin]]-[[German language|German]])<ref>''Correspondance mathématique et physique de quelques célèbres géomètres du XVIIIème siècle'' (Band 1), St.-Pétersbourg 1843, [https://books.google.com/books?id=OGMSAAAAIAAJ&pg=PA125 pp. 125–129].</ref>
| caption = Letter from Goldbach to Euler dated 7&nbsp;June 1742 ([[Latin]][[German language|German]])<ref name="Fuss">{{cite book | type=letter to [[Leonhard Euler]] |first=Christian|last=Goldbach |author-link=Christian Goldbach |chapter=Lettre XLIII |title=Correspondance mathématique et physique de quelques célèbres géomètres du XVIIIème siècle |language=de<!--Letter itself is in German--> |volume=1 |editor-first=Fuss |editor-last=P. H. |location=St. Petersburg |publisher=[[Russian Academy of Sciences|Imperial Academy of Sciences]] |year=1843 |url=https://books.google.com/books?id=OGMSAAAAIAAJ&pg=PA125 |pages=125–129}}</ref>
| field = [[Number theory]]
| field = [[Number theory]]
| conjectured by = [[Christian Goldbach]]
| conjectured by = [[Christian Goldbach]]
Line 18: Line 16:
'''Goldbach's conjecture''' is one of the oldest and best-known [[list of unsolved problems in mathematics|unsolved problem]]s in [[number theory]] and all of [[mathematics]]. It states that every [[even and odd numbers|even]] [[natural number]] greater than 2 is the sum of two [[prime number]]s.
'''Goldbach's conjecture''' is one of the oldest and best-known [[list of unsolved problems in mathematics|unsolved problem]]s in [[number theory]] and all of [[mathematics]]. It states that every [[even and odd numbers|even]] [[natural number]] greater than 2 is the sum of two [[prime number]]s.


The conjecture has been shown to hold for all integers less than {{val|4e18}} but remains unproven despite considerable effort.
The conjecture has been shown to hold for all integers less than {{val|4e18}}, but remains unproven despite considerable effort.


==History==
==History==
Line 24: Line 22:
=== Origins ===
=== Origins ===
On 7 June 1742, the [[Prussia]]n mathematician [[Christian Goldbach]] wrote a letter to [[Leonhard Euler]] (letter XLIII),<ref>{{cite web|url=http://eulerarchive.maa.org/correspondence/letters/OO0765|title=Letter XLIII, Goldbach to Euler|work=Correspondence of Leonhard Euler|publisher=Mathematical Association of America|date=7 June 1742|access-date=2025-01-19}}</ref> in which he proposed the following conjecture:
On 7 June 1742, the [[Prussia]]n mathematician [[Christian Goldbach]] wrote a letter to [[Leonhard Euler]] (letter XLIII),<ref>{{cite web|url=http://eulerarchive.maa.org/correspondence/letters/OO0765|title=Letter XLIII, Goldbach to Euler|work=Correspondence of Leonhard Euler|publisher=Mathematical Association of America|date=7 June 1742|access-date=2025-01-19}}</ref> in which he proposed the following conjecture:
{{block indent|text={{lang|de|dass jede Zahl, welche aus zweyen numeris primis zusammengesetzt ist, ein aggregatum so vieler numerorum primorum sey, als man will (die unitatem mit dazu gerechnet), bis auf die congeriem omnium unitatum}}<br />
Every integer that can be written as the sum of two primes can also be written as the sum of as many primes as one wishes, until all terms are units.}}
Goldbach was following the now-abandoned convention of [[Prime number#Primality of one|considering 1]] to be a [[prime number]],<ref name=MathWorldConj>{{MathWorld|title=Goldbach Conjecture|urlname=GoldbachConjecture}}</ref> so that a sum of units would be a sum of primes.
He then proposed a second conjecture in the margin of his letter, which implies the first:<ref>In the printed version published by P.&nbsp;H. Fuss [http://eulerarchive.maa.org//correspondence/letters/OO0765.pdf] 2 is misprinted as 1 in the marginal conjecture.</ref>
{{blockquote|text={{lang|de|Es scheinet wenigstens, dass eine jede Zahl, die grösser ist als 2, ein aggregatum trium numerorum primorum sey.}}<br />
It seems at least, that every integer greater than 2 can be written as the sum of three primes.}}


Euler replied in a letter dated 30 June 1742<ref>{{cite web|url=http://eulerarchive.maa.org/correspondence/letters/OO0766.pdf|title=Letter XLIV, Euler to Goldbach|work=Correspondence of Leonhard Euler|publisher=Mathematical Association of America|date=30 June 1742|access-date=2025-01-19}}</ref> and reminded Goldbach of an earlier conversation they had had ("{{lang|de|...&nbsp;so Ew vormals mit mir communicirt haben&nbsp;...}}"), in which Goldbach had remarked that the first of those two conjectures would follow from the statement
{{quote|Every integer that can be written as the sum of two primes can also be written as the sum of as many primes (including unity) as one wishes, until all terms are units.{{efn|In {{langx|de|...&nbsp;dass jede Zahl, welche aus zweyen numeris primis zusammengesetzt ist, ein aggregatum so vieler numerorum primorum sey, als man will (die unitatem mit dazu gerechnet), bis auf die congeriem omnium unitatum}}}}}}
 
Goldbach was following the now-abandoned convention of [[Prime number#Primality of one|considering 1]] to be a [[prime number]],<ref name=MathWorldConj>{{MathWorld|title=Goldbach Conjecture|urlname=GoldbachConjecture}}</ref> so that a sum of units would be a sum of primes. He then proposed a second conjecture in the margin of his letter, which implies the first:{{efn|In the printed version published by P.&nbsp;H. Fuss<ref name="Fuss"/> 2 is misprinted as 1 in the marginal conjecture.}}
 
{{quote|It seems at least, that every integer greater than 2 can be written as the sum of three primes.{{efn|In {{langx|de|Es scheinet wenigstens, dass eine jede Zahl, die grösser ist als 2, ein aggregatum trium numerorum primorum sey.}}}}}}
 
Euler replied in a letter dated 30 June 1742<ref>{{cite web|url=http://eulerarchive.maa.org/correspondence/letters/OO0766.pdf|title=Letter XLIV, Euler to Goldbach|work=Correspondence of Leonhard Euler|publisher=Mathematical Association of America|date=30 June 1742|access-date=2025-01-19}}</ref> and reminded Goldbach of an earlier conversation they had had ({{lang|de|"...&nbsp;so Ew vormals mit mir communicirt haben&nbsp;..."}}), in which Goldbach had remarked that the first of those two conjectures would follow from the statement
 
{{block indent|Every positive even integer can be written as the sum of two primes.}}
{{block indent|Every positive even integer can be written as the sum of two primes.}}
This is in fact equivalent to his second, marginal conjecture.
 
In the letter dated 30 June 1742, Euler stated:<ref name="theorema">{{cite web
This is in fact equivalent to his second, marginal conjecture. In the letter dated 30 June 1742, Euler stated:<ref name="theorema">{{cite web
  |last      = Ingham
  |last      = Ingham
  |first      = A. E.
  |first      = A. E.
Line 50: Line 49:
  | url = http://primes.utm.edu/glossary/page.php?sort=goldbachconjecture
  | url = http://primes.utm.edu/glossary/page.php?sort=goldbachconjecture
  | access-date = 2008-08-13 }}</ref>
  | access-date = 2008-08-13 }}</ref>
{{blockquote|text={{lang|de|Dass&nbsp;... ein jeder numerus par eine summa duorum primorum sey, halte ich für ein ganz gewisses theorema, ungeachtet ich dasselbe nicht demonstriren kann.}}<br />That&nbsp;... every even integer is a sum of two primes, I regard as a completely certain theorem, although I cannot prove it.}}
 
{{quote|That&nbsp;... every even integer is a sum of two primes, I regard as a completely certain theorem, although I cannot prove it.{{efn|In {{langx|de|Dass&nbsp;... ein jeder numerus par eine summa duorum primorum sey, halte ich für ein ganz gewisses theorema, ungeachtet ich dasselbe nicht demonstriren kann.}}}}}}


===Similar conjecture by Descartes===
===Similar conjecture by Descartes===
[[René Descartes]] wrote that "Every even number can be expressed as the sum of at most three primes."<ref>[https://real.mtak.hu/164172/1/PJ_DESCARTES_Conjecture1109.pdf ''On a conjecture of Descartes''] János Pintz, ELKH R´enyi Mathematical Institute of the Hungarian Academy of Sciences. Retrieved 11 January 2025.
[[René Descartes]] wrote that "Every even number can be expressed as the sum of at most three primes."<ref>Pintz, János. [https://real.mtak.hu/164172/1/PJ_DESCARTES_Conjecture1109.pdf "On a conjecture of Descartes"]. ELKH Rényi Mathematical Institute of the Hungarian Academy of Sciences. Retrieved 20 June 2025.</ref> The proposition is similar to, but weaker than, Goldbach's conjecture. [[Paul Erdős]] said that "Descartes actually discovered this before Goldbach&nbsp;... but it is better that the conjecture was named for Goldbach because, mathematically speaking, Descartes was infinitely rich and Goldbach was very poor."<ref>{{cite book |last=Hoffman |first=Paul |date=1998 |title=The Man Who Loved Only Numbers |location= United States|publisher=Hyperion Books |page=36 |isbn=978-0786863624}}</ref>
</ref> The proposition is similar to, but weaker than, Goldbach's conjecture. [[Paul Erdős]] said that "Descartes actually discovered this before Goldbach... but it is better that the conjecture was named for Goldbach because, mathematically speaking, Descartes was infinitely rich and Goldbach was very poor."<ref>{{cite book |last=Hoffman |first=Paul |date=1998|title=The Man Who Loved Only Numbers |location= United States|publisher=Hyperion Books |page=36 |isbn=978-0786863624}}</ref>


=== Partial results ===
=== Partial results ===
Goldbach's conjecture involving the sum of two primes is much more difficult than the [[weak Goldbach conjecture]], which says that every odd integer greater than 5 is the sum of three primes. Using [[Ivan_Vinogradov#Mathematical_contributions|Vinogradov's method]], [[Nikolai Chudakov]],<ref>{{Cite journal |last=Chudakov |first=Nikolai G. |year=1937 |title={{lang|ru|О проблеме Гольдбаха}} |trans-title=On the Goldbach problem |journal=[[Doklady Akademii Nauk SSSR]] |volume=17 |pages=335–338}}</ref> [[Johannes van der Corput]],<ref>{{cite journal |last=Van der Corput |first=J. G. |year=1938 |title=Sur l'hypothèse de Goldbach |url=http://www.dwc.knaw.nl/DL/publications/PU00016746.pdf |journal=Proc. Akad. Wet. Amsterdam |language=fr |volume=41 |pages=76–80}}</ref> and [[Theodor Estermann]]<ref>{{cite journal |last=Estermann |first=T. |year=1938 |title=On Goldbach's problem: proof that almost all even positive integers are sums of two primes |journal=Proc. London Math. Soc. |series=2 |volume=44 |pages=307–314 |doi=10.1112/plms/s2-44.4.307}}</ref> showed (1937–1938) that [[almost all]] even numbers can be written as the sum of two primes (in the sense that the fraction of even numbers up to some {{mvar|N}} which can be so written tends towards 1 as {{mvar|N}} increases). In 1930, [[Lev Schnirelmann]] proved that any [[natural number]] greater than 1 can be written as the sum of not more than {{mvar|C}} prime numbers, where {{mvar|C}} is an effectively computable constant; see [[Schnirelmann density]].<ref>Schnirelmann, L. G. (1930). "[http://mi.mathnet.ru/eng/umn/y1939/i6/p9 On the additive properties of numbers]", first published in "Proceedings of the Don Polytechnic Institute in Novocherkassk" (in Russian), vol '''14''' (1930), pp. 3–27, and reprinted in "Uspekhi Matematicheskikh Nauk" (in Russian), 1939, no. 6, 9–25.</ref><ref>Schnirelmann, L. G. (1933). First published as "[https://link.springer.com/article/10.1007/BF01448914 Über additive Eigenschaften von Zahlen]" in "[[Mathematische Annalen]]" (in German), vol. '''107''' (1933), 649–690, and reprinted as "[http://mi.mathnet.ru/eng/umn/y1940/i7/p7 On the additive properties of numbers]" in "Uspekhi Matematicheskikh Nauk" (in Russian), 1940, no. 7, 7–46.</ref> Schnirelmann's constant is the lowest number {{mvar|C}} with this property. Schnirelmann himself obtained {{math|''C'' < {{val|800,000}}}}. This result was subsequently enhanced by many authors, such as [[Olivier Ramaré]], who in 1995 showed that every even number {{math|''n'' ≥ 4}} is in fact the sum of at most 6 primes. The best known result currently stems from the proof of the weak Goldbach conjecture by [[Harald Helfgott]],<ref>{{cite arXiv |eprint=1312.7748 |class=math.NT |first=H. A. |last=Helfgott |title=The ternary Goldbach conjecture is true |date=2013}}</ref> which directly implies that every even number {{math|''n'' ≥ 4}} is the sum of at most 4 primes.<ref>{{Cite journal |last=Sinisalo |first=Matti K. |date=Oct 1993 |title=Checking the Goldbach Conjecture up to 4 ⋅ 10<sup>11</sup> |url=https://www.ams.org/journals/mcom/1993-61-204/S0025-5718-1993-1185250-6/S0025-5718-1993-1185250-6.pdf |publisher=American Mathematical Society |volume=61 |issue=204 |pages=931–934 |citeseerx=10.1.1.364.3111 |doi=10.2307/2153264 |jstor=2153264 |periodical=Mathematics of Computation}}</ref><ref>{{cite book |last=Rassias |first=M. Th. |title=Goldbach's Problem: Selected Topics |publisher=Springer |year=2017}}</ref>
Goldbach's conjecture involving the sum of two primes is much more difficult than the [[weak Goldbach conjecture]], which says that every odd integer greater than 5 is the sum of three primes. Using [[Ivan Vinogradov#Mathematical contributions|Vinogradov's method]], [[Nikolai Chudakov]],<ref>{{Cite journal |last=Chudakov |first=Nikolai G. |year=1937 |script-title=ru:О проблеме Гольдбаха |trans-title=On the Goldbach problem |journal=[[Doklady Akademii Nauk SSSR]] |volume=17 |pages=335–338}}</ref> [[Johannes van der Corput]],<ref>{{cite journal |last=Van der Corput |first=J. G. |year=1938 |title=Sur l'hypothèse de Goldbach |url=http://www.dwc.knaw.nl/DL/publications/PU00016746.pdf |journal=Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen Amsterdam |language=fr |volume=41 |pages=76–80}}</ref> and [[Theodor Estermann]]<ref>{{cite journal |last=Estermann |first=T. |year=1938 |title=On Goldbach's problem: proof that almost all even positive integers are sums of two primes |journal=Proceedings of the London Mathematical Society |series=2 |volume=44 |pages=307–314 |doi=10.1112/plms/s2-44.4.307}}</ref> showed (1937–1938) that [[almost all]] even numbers can be written as the sum of two primes (in the sense that the fraction of even numbers up to some {{mvar|N}} which can be so written tends towards 1 as {{mvar|N}} increases). In 1930, [[Lev Schnirelmann]] proved that any [[natural number]] greater than 1 can be written as the sum of not more than {{mvar|C}} prime numbers, where {{mvar|C}} is an effectively computable constant; see [[Schnirelmann density]].<ref>Schnirelmann, L. G. (1930). [http://mi.mathnet.ru/eng/umn/y1939/i6/p9 'On the additive properties of numbers"]. First published in ''Proceedings of the Don Polytechnic Institute in Novocherkassk'' (in Russian), vol '''14''' (1930), pp. 3–27, and reprinted in ''Uspekhi Matematicheskikh Nauk'' (in Russian), 1939, no. 6, 9–25.</ref><ref>Schnirelmann, L. G. (1933). First published as [https://link.springer.com/article/10.1007/BF01448914 "Über additive Eigenschaften von Zahlen"]. In ''[[Mathematische Annalen]]'' (in German), vol. '''107''' (1933), 649–690, and reprinted as [http://mi.mathnet.ru/eng/umn/y1940/i7/p7 "On the additive properties of numbers"] in ''Uspekhi Matematicheskikh Nauk'' (in Russian), 1940, no. 7, 7–46.</ref> Schnirelmann's constant is the lowest number {{mvar|C}} with this property. Schnirelmann himself obtained {{math|''C'' < {{val|800,000}}}}. This result was subsequently enhanced by many authors, such as [[Olivier Ramaré]], who in 1995 showed that every even number {{math|''n'' ≥ 4}} is in fact the sum of at most 6 primes. The best known result currently stems from the proof of the weak Goldbach conjecture by [[Harald Helfgott]],<ref>{{cite arXiv |eprint=1312.7748 |class=math.NT |first=H. A. |last=Helfgott |title=The ternary Goldbach conjecture is true |date=2013}}</ref> which directly implies that every even number {{math|''n'' ≥ 4}} is the sum of at most 4 primes.<ref>{{Cite journal |last=Sinisalo |first=Matti K. |date=October 1993 |title=Checking the Goldbach Conjecture up to 4 ⋅ 10<sup>11</sup> |url=https://www.ams.org/journals/mcom/1993-61-204/S0025-5718-1993-1185250-6/S0025-5718-1993-1185250-6.pdf |publisher=American Mathematical Society |volume=61 |issue=204 |pages=931–934 |citeseerx=10.1.1.364.3111 |doi=10.2307/2153264 |jstor=2153264 |periodical=Mathematics of Computation}}</ref><ref>{{cite book |last=Rassias |first=M. Th. |title=Goldbach's Problem: Selected Topics |publisher=Springer |year=2017}}</ref>


In 1924, Hardy and Littlewood showed under the assumption of the [[generalized Riemann hypothesis]] that the number of even numbers up to {{mvar|X}} violating the Goldbach conjecture is [[Inequality (mathematics)|much less than]] {{math|''X''<sup>{{1/2}} + ''c''</sup>}} for small {{mvar|c}}.<ref>See, for example, ''A new explicit formula in the additive theory of primes with applications I. The explicit formula for the Goldbach and Generalized Twin Prime Problems'' by Janos Pintz.</ref>
In 1924, Hardy and Littlewood showed under the assumption of the [[generalized Riemann hypothesis]] that the number of even numbers up to {{mvar|X}} violating the Goldbach conjecture is [[Inequality (mathematics)|much less than]] {{math|''X''<sup>{{1/2}} + ''c''</sup>}} for small {{mvar|c}}.<ref>See, for example, ''A new explicit formula in the additive theory of primes with applications I. The explicit formula for the Goldbach and Generalized Twin Prime Problems'' by Janos Pintz.</ref>{{fcn|date=June 2025}}


In 1948, using [[sieve theory]] methods, [[Alfréd Rényi]] showed that every sufficiently large even number can be written as the sum of a prime and an [[almost prime]] with at most {{mvar|K}} factors.<ref name="Alfréd Rényi 1948">{{cite journal |last=Rényi |first=A. A. |year=1948 |title=On the representation of an even number as the sum of a prime and an almost prime |journal=Izvestiya Akademii Nauk SSSR. Seriya Matematicheskaya |language=Russian |volume=12 |pages=57–78}}</ref> [[Chen Jingrun]] showed in 1973 using sieve theory that every [[sufficiently large]] even number can be written as the sum of either two primes, or a prime and a [[semiprime]] (the product of two primes).<ref>{{cite journal |last=Chen |first=J. R. |year=1973 |title=On the representation of a larger even integer as the sum of a prime and the product of at most two primes |journal=Sci. Sinica |volume=16 |pages=157–176}}</ref> See [[Chen's theorem]] for further information.
In 1948, using [[sieve theory]] methods, [[Alfréd Rényi]] showed that every sufficiently large even number can be written as the sum of a prime and an [[almost prime]] with at most {{mvar|K}} factors.<ref name="Alfréd Rényi 1948">{{cite journal |last=Rényi |first=A. A. |year=1948 |title=On the representation of an even number as the sum of a prime and an almost prime |journal=Izvestiya Akademii Nauk SSSR. Seriya Matematicheskaya |language=ru |volume=12 |pages=57–78}}</ref> [[Chen Jingrun]] showed in 1973 using sieve theory that every [[sufficiently large]] even number can be written as the sum of either two primes, or a prime and a [[semiprime]] (the product of two primes).<ref>{{cite journal |last=Chen |first=J. R. |year=1973 |title=On the representation of a larger even integer as the sum of a prime and the product of at most two primes |journal=Scientia Sinica |volume=16 |pages=157–176}}</ref> See [[Chen's theorem]] for further information.


In 1975, [[Hugh Lowell Montgomery]] and [[Bob Vaughan]] showed that "most" even numbers are expressible as the sum of two primes. More precisely, they showed that there exist positive constants {{mvar|c}} and {{mvar|C}} such that for all sufficiently large numbers {{mvar|N}}, every even number less than {{mvar|N}} is the sum of two primes, with at most {{math|''CN''<sup>1 − ''c''</sup>}} exceptions. In particular, the set of even integers that are not the sum of two primes has [[natural density|density]] zero.
In 1975, [[Hugh Lowell Montgomery]] and [[Bob Vaughan]] showed that "most" even numbers are expressible as the sum of two primes. More precisely, they showed that there exist positive constants {{mvar|c}} and {{mvar|C}} such that for all sufficiently large numbers {{mvar|N}}, every even number less than {{mvar|N}} is the sum of two primes, with at most {{math|''CN''<sup>1 − ''c''</sup>}} exceptions. In particular, the set of even integers that are not the sum of two primes has [[natural density|density]] zero.


In 1951, [[Yuri Linnik]] proved the existence of a constant {{mvar|K}} such that every sufficiently large even number is the sum of two primes and at most {{mvar|K}} powers of 2. [[János Pintz]] and [[Imre Z. Ruzsa|Imre Ruzsa]] found in 2020 that {{math|1=''K'' = 8}} works.<ref>{{Cite journal |last1=Pintz |first1=J. |last2=Ruzsa |first2=I. Z. |date=2020-08-01 |title=On Linnik's approximation to Goldbach's problem. II |url=https://doi.org/10.1007/s10474-020-01077-8 |journal=[[Acta Mathematica Hungarica]] |language=en |volume=161 |issue=2 |pages=569–582 |doi=10.1007/s10474-020-01077-8 |s2cid=54613256 |issn=1588-2632 |authorlink1=János Pintz}}</ref> Assuming the [[generalized Riemann hypothesis]], {{math|1=''K'' = 7}} also works, as shown by [[Roger Heath-Brown]] and [[Jan-Christoph Schlage-Puchta]] in 2002.<ref>{{cite journal |last1=Heath-Brown |first1=D. R. |last2=Puchta |first2=J. C. |year=2002 |title=Integers represented as a sum of primes and powers of two |journal=[[Asian Journal of Mathematics]] |volume=6 |issue=3 |pages=535–565 |arxiv=math.NT/0201299 |bibcode=2002math......1299H |doi=10.4310/AJM.2002.v6.n3.a7 |s2cid=2843509}}</ref>
In 1951, [[Yuri Linnik]] proved the existence of a constant {{mvar|K}} such that every sufficiently large even number is the sum of two primes and at most {{mvar|K}} powers of 2. [[János Pintz]] and [[Imre Z. Ruzsa|Imre Ruzsa]] found in 2020 that {{math|1=''K'' = 8}} works.<ref>{{Cite journal |last1=Pintz |first1=J. |last2=Ruzsa |first2=I. Z. |date=2020-08-01 |title=On Linnik's approximation to Goldbach's problem. II |url=https://doi.org/10.1007/s10474-020-01077-8 |journal=[[Acta Mathematica Hungarica]] |language=en |volume=161 |issue=2 |pages=569–582 |doi=10.1007/s10474-020-01077-8 |s2cid=54613256 |issn=1588-2632 |authorlink1=János Pintz|url-access=subscription }}</ref> Assuming the [[generalized Riemann hypothesis]], {{math|1=''K'' = 7}} also works, as shown by [[Roger Heath-Brown]] and [[Jan-Christoph Schlage-Puchta]] in 2002.<ref>{{cite journal |last1=Heath-Brown |first1=D. R. |last2=Puchta |first2=J. C. |year=2002 |title=Integers represented as a sum of primes and powers of two |journal=[[Asian Journal of Mathematics]] |volume=6 |issue=3 |pages=535–565 |arxiv=math.NT/0201299 |bibcode=2002math......1299H |doi=10.4310/AJM.2002.v6.n3.a7 |s2cid=2843509}}</ref>


A proof for the weak conjecture was submitted in 2013 by [[Harald Helfgott]] to ''[[Annals of Mathematics Studies]]'' series. Although the article was accepted, Helfgott decided to undertake the major modifications suggested by the referee. Despite several revisions, Helfgott's proof has not yet appeared in a peer-reviewed publication.<ref name="Helfgott 2013">{{cite arXiv |eprint=1305.2897 |class=math.NT |first=H. A. |last=Helfgott |title=Major arcs for Goldbach's theorem |year=2013}}</ref><ref name="Helfgott 2012">{{cite arXiv |eprint=1205.5252 |class=math.NT |first=H. A. |last=Helfgott |title=Minor arcs for Goldbach's problem |year=2012}}</ref><ref>{{Cite web |title=Harald Andrés Helfgott |url=https://webusers.imj-prg.fr/~harald.helfgott/anglais/book.html |access-date=2021-04-06 |publisher=Institut de Mathématiques de Jussieu-Paris Rive Gauche}}</ref> The weak conjecture is implied by the Goldbach conjecture, as if {{math|''n'' − 3}} is a sum of two primes, then {{mvar|n}} is a sum of three primes. However, the converse implication and thus the Goldbach conjecture would remain unproven if Helfgott's proof is correct.
A proof for the weak conjecture was submitted in 2013 by [[Harald Helfgott]] to ''[[Annals of Mathematics Studies]]'' series. Although the article was accepted, Helfgott decided to undertake the major modifications suggested by the referee. Despite several revisions, Helfgott's proof has not yet appeared in a peer-reviewed publication.<ref name="Helfgott 2013">{{cite arXiv |eprint=1305.2897 |class=math.NT |first=H. A. |last=Helfgott |title=Major arcs for Goldbach's theorem |year=2013}}</ref><ref name="Helfgott 2012">{{cite arXiv |eprint=1205.5252 |class=math.NT |first=H. A. |last=Helfgott |title=Minor arcs for Goldbach's problem |year=2012}}</ref><ref>{{Cite web |title=Harald Andrés Helfgott |url=https://webusers.imj-prg.fr/~harald.helfgott/anglais/book.html |access-date=2021-04-06 |publisher=Institut de Mathématiques de Jussieu-Paris Rive Gauche}}</ref> The weak conjecture is implied by the Goldbach conjecture, as if {{math|''n'' − 3}} is a sum of two primes, then {{mvar|n}} is a sum of three primes. However, the converse implication and thus the Goldbach conjecture would remain unproven if Helfgott's proof is correct.


=== Computational results ===
=== Computational results ===
For small values of {{mvar|n}}, the strong Goldbach conjecture (and hence the weak Goldbach conjecture) can be verified directly. For instance, in 1938, Nils Pipping laboriously verified the conjecture up to {{math|''n'' {{=}} {{val|100,000}}}}.<ref>Pipping, Nils (1890–1982), "Die Goldbachsche Vermutung und der Goldbach-Vinogradowsche Satz". Acta Acad. Aboensis, Math. Phys. 11, 4–25, 1938.</ref> With the advent of computers, many more values of {{mvar|n}} have been checked; T. Oliveira e Silva ran a distributed computer search that has verified the conjecture for {{math|''n'' ≤ {{val|4e18}}}} (and double-checked up to {{val|4e17}}) as of 2013. One record from this search is that {{val|3,325,581,707,333,960,528}} is the smallest number that cannot be written as a sum of two primes where one is smaller than 9781.<ref name=":0">Tomás Oliveira e Silva, [https://sweet.ua.pt/tos/goldbach.html Goldbach conjecture verification]. Retrieved 20 April 2024.</ref>
For small values of {{mvar|n}}, the strong Goldbach conjecture (and hence the weak Goldbach conjecture) can be verified directly. For instance, in 1938, Nils Pipping laboriously verified the conjecture up to {{math|''n'' {{=}} {{val|100,000}}}}.<ref>Pipping, Nils (1890–1982). "Die Goldbachsche Vermutung und der Goldbach-Vinogradowsche Satz". ''Acta Academiae Aboensis, Mathematica et physica'' 11, 4–25, 1938.</ref> With the advent of computers, many more values of {{mvar|n}} have been checked; T. Oliveira e Silva ran a distributed computer search that has verified the conjecture for {{math|''n'' ≤ {{val|4e18}}}} (and double-checked up to {{val|4e17}}) as of 2013. One record from this search is that {{val|3,325,581,707,333,960,528}} is the smallest number that cannot be written as a sum of two primes where one is smaller than 9781.<ref name=":0">Tomás Oliveira e Silva, [https://sweet.ua.pt/tos/goldbach.html "Goldbach conjecture verification"]. Retrieved 20 April 2024.</ref>{{fcn|date=June 2025}}


=== In popular culture ===
=== In popular culture ===
''Goldbach's Conjecture'' ({{zh|t=哥德巴赫猜想}}) is the title of the biography of Chinese mathematician and number theorist [[Chen Jingrun]], written by [[Xu Chi]].
''Goldbach's Conjecture'' ({{zh|t=哥德巴赫猜想}}) is the title of the biography of Chinese mathematician and number theorist [[Chen Jingrun]], written by [[Xu Chi]].


The conjecture is a central point in the plot of the 1992 novel ''[[Uncle Petros and Goldbach's Conjecture]]'' by Greek author [[Apostolos Doxiadis]], in the short story "[[Sixty Million Trillion Combinations]]" by [[Isaac Asimov]] and also in the 2008 mystery novel ''No One You Know'' by [[Michelle Richmond]].<ref>{{Cite web |title=MathFiction: No One You Know (Michelle Richmond) |url=http://kasmana.people.cofc.edu/MATHFICT/mfview.php?callnumber=mf711 |website=kasmana.people.cofc.edu}}</ref>
The conjecture is a central point in the plot of the 1992 novel ''[[Uncle Petros and Goldbach's Conjecture]]'' by Greek author [[Apostolos Doxiadis]], in the short story "[[Sixty Million Trillion Combinations]]" by [[Isaac Asimov]] and also in the 2008 mystery novel ''No One You Know'' by [[Michelle Richmond]].<ref>{{Cite web |title=MathFiction: No One You Know (Michelle Richmond) |type=book review |url=http://kasmana.people.cofc.edu/MATHFICT/mfview.php?callnumber=mf711 |website=Mathematical Fiction |last=Kasman |first=Alex |publisher=College of Charleston}}</ref>


Goldbach's conjecture is part of the plot of the 2007 Spanish film ''[[Fermat's Room]]''.
Goldbach's conjecture is part of the plot of the 2007 Spanish film ''[[Fermat's Room]]''.


Goldbach's conjecture is featured as the main topic of research of the titular character Marguerite in the 2023 French-Swiss film ''[[Marguerite's Theorem]]''.<ref> Odile Morain [https://www.francetvinfo.fr/culture/cinema/sorties-de-films/le-theoreme-de-marguerite-jean-pierre-darroussin-et-ella-rumpf-dans-la-folie-creatrice-des-maths_6147984.html ''Le Théorème de Marguerite''], in
Goldbach's conjecture is featured as the main topic of research of the titular character Marguerite in the 2023 French-Swiss film ''[[Marguerite's Theorem]]''.<ref>Morain, Odile. [https://www.francetvinfo.fr/culture/cinema/sorties-de-films/le-theoreme-de-marguerite-jean-pierre-darroussin-et-ella-rumpf-dans-la-folie-creatrice-des-maths_6147984.html ''Le Théorème de Marguerite''].
[[France Télévisions|franceinfo:culture]]</ref>
[[France Télévisions|franceinfo:culture]]</ref>


Line 106: Line 105:
A very crude version of the [[heuristic]] probabilistic argument (for the strong form of the Goldbach conjecture) is as follows. The [[prime number theorem]] asserts that an integer {{mvar|m}} selected at random has roughly a {{math|{{sfrac|1|ln ''m''}}}} chance of being prime. Thus if {{mvar|n}} is a large even integer and {{mvar|m}} is a number between 3 and {{math|{{sfrac|''n''|2}}}}, then one might expect the probability of {{mvar|m}} and {{math|''n'' − ''m''}} simultaneously being prime to be {{math|{{sfrac|1|ln ''m'' ln(''n'' − ''m'')}}}}. If one pursues this heuristic, one might expect the total number of ways to write a large even integer {{mvar|n}} as the sum of two odd primes to be roughly
A very crude version of the [[heuristic]] probabilistic argument (for the strong form of the Goldbach conjecture) is as follows. The [[prime number theorem]] asserts that an integer {{mvar|m}} selected at random has roughly a {{math|{{sfrac|1|ln ''m''}}}} chance of being prime. Thus if {{mvar|n}} is a large even integer and {{mvar|m}} is a number between 3 and {{math|{{sfrac|''n''|2}}}}, then one might expect the probability of {{mvar|m}} and {{math|''n'' − ''m''}} simultaneously being prime to be {{math|{{sfrac|1|ln ''m'' ln(''n'' − ''m'')}}}}. If one pursues this heuristic, one might expect the total number of ways to write a large even integer {{mvar|n}} as the sum of two odd primes to be roughly


: <math>\sum_{m=3}^\frac{n}{2} \frac{1}{\ln m} \frac{1}{\ln(n - m)} \approx \frac{n}{2 (\ln n)^2}.</math>
<math display="block">\sum_{m=3}^\frac{n}{2} \frac{1}{\ln m} \frac{1}{\ln(n - m)} \approx \frac{n}{2 (\ln n)^2}.</math>


Since {{math|ln ''n'' ≪ {{sqrt|''n''}}}}, this quantity goes to infinity as {{mvar|n}} increases, and one would expect that every large even integer has not just one representation as the sum of two primes, but in fact very many such representations.
Since {{math|ln ''n'' ≪ {{sqrt|''n''}}}}, this quantity goes to infinity as {{mvar|n}} increases, and one would expect that every large even integer has not just one representation as the sum of two primes, but in fact very many such representations.
Line 112: Line 111:
This heuristic argument is actually somewhat inaccurate because it assumes that the events of {{mvar|m}} and {{math|''n'' − ''m''}} being prime are [[statistical independence|statistically independent]] of each other. For instance, if {{mvar|m}} is odd, then {{math|''n'' − ''m''}} is also odd, and if {{mvar|m}} is even, then {{math|''n'' − ''m''}} is even, a non-trivial relation because, besides the number 2, only odd numbers can be prime. Similarly, if {{mvar|n}} is divisible by 3, and {{mvar|m}} was already a prime other than 3, then {{math|''n'' − ''m''}} would also be [[coprime]] to 3 and thus be slightly more likely to be prime than a general number. Pursuing this type of analysis more carefully, [[G. H. Hardy]] and [[John Edensor Littlewood]] in 1923 conjectured (as part of their ''[[Twin prime#First Hardy–Littlewood conjecture|Hardy–Littlewood prime tuple conjecture]]'') that for any fixed {{math|''c'' ≥ 2}}, the number of representations of a large integer {{mvar|n}} as the sum of {{mvar|c}} primes {{math|''n'' {{=}} ''p''<sub>1</sub> + ⋯ + ''p<sub>c</sub>''}} with {{math|''p''<sub>1</sub> ≤ ⋯ ≤ ''p<sub>c</sub>''}} should be [[asymptotic analysis|asymptotically]] equal to
This heuristic argument is actually somewhat inaccurate because it assumes that the events of {{mvar|m}} and {{math|''n'' − ''m''}} being prime are [[statistical independence|statistically independent]] of each other. For instance, if {{mvar|m}} is odd, then {{math|''n'' − ''m''}} is also odd, and if {{mvar|m}} is even, then {{math|''n'' − ''m''}} is even, a non-trivial relation because, besides the number 2, only odd numbers can be prime. Similarly, if {{mvar|n}} is divisible by 3, and {{mvar|m}} was already a prime other than 3, then {{math|''n'' − ''m''}} would also be [[coprime]] to 3 and thus be slightly more likely to be prime than a general number. Pursuing this type of analysis more carefully, [[G. H. Hardy]] and [[John Edensor Littlewood]] in 1923 conjectured (as part of their ''[[Twin prime#First Hardy–Littlewood conjecture|Hardy–Littlewood prime tuple conjecture]]'') that for any fixed {{math|''c'' ≥ 2}}, the number of representations of a large integer {{mvar|n}} as the sum of {{mvar|c}} primes {{math|''n'' {{=}} ''p''<sub>1</sub> + ⋯ + ''p<sub>c</sub>''}} with {{math|''p''<sub>1</sub> ≤ ⋯ ≤ ''p<sub>c</sub>''}} should be [[asymptotic analysis|asymptotically]] equal to


: <math>\left(\prod_p \frac{p \gamma_{c,p}(n)}{(p - 1)^c}\right)
<math display="block">\left(\prod_p \frac{p \gamma_{c,p}(n)}{(p - 1)^c}\right)
  \int_{2 \leq x_1 \leq \cdots \leq x_c: x_1 + \cdots + x_c = n} \frac{dx_1 \cdots dx_{c-1}}{\ln x_1 \cdots \ln x_c},</math>
  \int_{2 \leq x_1 \leq \cdots \leq x_c: x_1 + \cdots + x_c = n} \frac{dx_1 \cdots dx_{c-1}}{\ln x_1 \cdots \ln x_c},</math>


where the product is over all primes {{mvar|p}}, and {{math|''γ''<sub>''c'',''p''</sub>(''n'')}} is the number of solutions to the equation {{math|''n'' {{=}} ''q''<sub>1</sub> + ⋯ + ''q<sub>c</sub>'' mod ''p''}} in [[modular arithmetic]], subject to the [[Constraint (mathematics)|constraints]] {{math|''q''<sub>1</sub>, , ''q<sub>c</sub>'' ≠ 0 mod ''p''}}. This formula has been rigorously proven to be asymptotically valid for {{math|''c'' ≥ 3}} from the work of [[Ivan Matveevich Vinogradov]], but is still only a conjecture when {{math|''c'' {{=}} 2}}.{{Citation needed|date=January 2016}} In the latter case, the above formula simplifies to 0 when {{mvar|n}} is odd, and to
where the product is over all primes {{mvar|p}}, and {{math|''γ''<sub>''c'',''p''</sub>(''n'')}} is the number of solutions to the equation {{math|''n'' {{=}} ''q''<sub>1</sub> + ⋯ + ''q<sub>c</sub>'' mod ''p''}} in [[modular arithmetic]], subject to the [[Constraint (mathematics)|constraints]] {{math|''q''<sub>1</sub>, ..., ''q<sub>c</sub>'' ≠ 0 mod ''p''}}. This formula has been rigorously proven to be asymptotically valid for {{math|''c'' ≥ 3}} from the work of [[Ivan Matveevich Vinogradov]], but is still only a conjecture when {{math|''c'' {{=}} 2}}.{{Citation needed|date=January 2016}} In the latter case, the above formula simplifies to 0 when {{mvar|n}} is odd, and to


: <math>
<math display="block">
  2 \Pi_2 \left(\prod_{p \mid n; p \geq 3} \frac{p - 1}{p - 2}\right) \int_2^n \frac{dx}{(\ln x)^2}
  2 \Pi_2 \left(\prod_{p \mid n; p \geq 3} \frac{p - 1}{p - 2}\right) \int_2^n \frac{dx}{(\ln x)^2}
  \approx 2 \Pi_2 \left(\prod_{p \mid n; p \geq 3} \frac{p - 1}{p - 2}\right) \frac{n}{(\ln n)^2}
  \approx 2 \Pi_2 \left(\prod_{p \mid n; p \geq 3} \frac{p - 1}{p - 2}\right) \frac{n}{(\ln n)^2}
Line 124: Line 123:
when {{mvar|n}} is even, where {{math|Π<sub>2</sub>}} is [[Twin prime#First Hardy–Littlewood conjecture|Hardy–Littlewood's twin prime constant]]
when {{mvar|n}} is even, where {{math|Π<sub>2</sub>}} is [[Twin prime#First Hardy–Littlewood conjecture|Hardy–Littlewood's twin prime constant]]


: <math>\Pi_2 := \prod_{p\;{\rm prime} \ge 3} \left(1 - \frac{1}{(p-1)^2}\right) \approx 0.66016\,18158\,46869\,57392\,78121\,10014\dots</math>
<math display="block">\Pi_2 := \prod_{p\;{\rm prime} \ge 3} \left(1 - \frac{1}{(p-1)^2}\right) \approx 0.66016\,18158\,46869\,57392\,78121\,10014\dots</math>


This is sometimes known as the ''extended Goldbach conjecture''. The strong Goldbach conjecture is in fact very similar to the [[Twin prime#Twin prime conjecture|twin prime]] conjecture, and the two conjectures are believed to be of roughly comparable difficulty.
This is sometimes known as the ''extended Goldbach conjecture''. The strong Goldbach conjecture is in fact very similar to the [[Twin prime#Twin prime conjecture|twin prime]] conjecture, and the two conjectures are believed to be of roughly comparable difficulty.
Line 143: Line 142:
* The Goldbach conjecture for [[practical number]]s, a prime-like sequence of integers, was stated by Margenstern in 1984,<ref>{{cite journal |first=M. |last=Margenstern |title=Results and conjectures about practical numbers |journal= [[Comptes rendus de l'Académie des Sciences]]|volume=299 |year=1984 |pages=895–898 }}</ref> and proved by [[Giuseppe Melfi|Melfi]] in 1996:<ref>{{cite journal |first=G. |last=Melfi |title=On two conjectures about practical numbers |journal= [[Journal of Number Theory]] |volume=56|year=1996 | pages=205–210 |doi=10.1006/jnth.1996.0012|doi-access=free }}</ref> every even number is a sum of two practical numbers.
* The Goldbach conjecture for [[practical number]]s, a prime-like sequence of integers, was stated by Margenstern in 1984,<ref>{{cite journal |first=M. |last=Margenstern |title=Results and conjectures about practical numbers |journal= [[Comptes rendus de l'Académie des Sciences]]|volume=299 |year=1984 |pages=895–898 }}</ref> and proved by [[Giuseppe Melfi|Melfi]] in 1996:<ref>{{cite journal |first=G. |last=Melfi |title=On two conjectures about practical numbers |journal= [[Journal of Number Theory]] |volume=56|year=1996 | pages=205–210 |doi=10.1006/jnth.1996.0012|doi-access=free }}</ref> every even number is a sum of two practical numbers.
* [[Harvey Dubner]] proposed a strengthening of the Goldbach conjecture that states that every even integer greater than 4208 is the sum of two [[twin prime]]s (not necessarily belonging to the same pair).<ref>{{Cite web|url=https://oeis.org/A007534/a007534.pdf|title=TWIN PRIME CONJECTURES|website=oeis.org}}</ref>{{better source|reason= This is raw html, although it seems to have been published in Recreational Mathematics|date=September 2023}} Only 34 even integers less than 4208 are not the sum of two twin primes; Dubner has verified computationally that this list is complete up to <math>2\cdot 10^{10}.</math><ref>{{Cite OEIS|A007534|name=Even numbers that are not the sum of a pair of twin primes}}</ref>{{check|reason=This source states 10^9, and the other source is unclear on the limit|date=September 2023}} A proof of this stronger conjecture would not only imply Goldbach's conjecture, but also the [[twin prime conjecture]].
* [[Harvey Dubner]] proposed a strengthening of the Goldbach conjecture that states that every even integer greater than 4208 is the sum of two [[twin prime]]s (not necessarily belonging to the same pair).<ref>{{Cite web|url=https://oeis.org/A007534/a007534.pdf|title=TWIN PRIME CONJECTURES|website=oeis.org}}</ref>{{better source|reason= This is raw html, although it seems to have been published in Recreational Mathematics|date=September 2023}} Only 34 even integers less than 4208 are not the sum of two twin primes; Dubner has verified computationally that this list is complete up to <math>2\cdot 10^{10}.</math><ref>{{Cite OEIS|A007534|name=Even numbers that are not the sum of a pair of twin primes}}</ref>{{check|reason=This source states 10^9, and the other source is unclear on the limit|date=September 2023}} A proof of this stronger conjecture would not only imply Goldbach's conjecture, but also the [[twin prime conjecture]].
* According to [[Bertrand's postulate]], for every integer <math>n > 1</math>, there is always at least one prime <math>p</math> such that <math>n < p < 2n.</math> If the postulate were false, there would exist some integer <math>n</math> for which no prime numbers lie between <math>n</math> and <math>2n</math>, making it impossible to express <math>2n</math> as a sum of two primes.


Goldbach's conjecture is used when studying computational complexity.<ref name="quanta">{{cite web |url=https://www.quantamagazine.org/how-the-slowest-computer-programs-illuminate-maths-fundamental-limits-20201210/ |title=How the Slowest Computer Programs Illuminate Math's Fundamental Limits|date=10 December 2020 }}</ref>  The connection is made through the [[Busy Beaver]] function, where BB(''n'') is the maximum number of steps taken by any ''n'' state [[Turing machine]] that halts. There is a 27-state Turing machine that halts if and only if Goldbach's conjecture is false.<ref name="quanta"/> Hence if BB(27) was known, and the Turing machine did not stop in that number of steps, it would be known to run forever and hence no counterexamples exist (which proves the conjecture true). This is a completely impractical way to settle the conjecture; instead it is used to suggest that BB(27) will be very hard to compute, at least as difficult as settling the Goldbach conjecture.
Goldbach's conjecture is used when studying computational complexity.<ref name="quanta">{{cite web |url=https://www.quantamagazine.org/how-the-slowest-computer-programs-illuminate-maths-fundamental-limits-20201210/ |title=How the Slowest Computer Programs Illuminate Math's Fundamental Limits|date=10 December 2020 }}</ref>  The connection is made through the [[Busy Beaver]] function, where BB(''n'') is the maximum number of steps taken by any ''n'' state [[Turing machine]] that halts. There is a 27-state Turing machine that halts if and only if Goldbach's conjecture is false.<ref name="quanta"/> Hence if BB(27) was known, and the Turing machine did not stop in that number of steps, it would be known to run forever and hence no counterexamples exist (which proves the conjecture true). This is a completely impractical way to settle the conjecture; instead it is used to suggest that BB(27) will be very hard to compute, at least as difficult as settling the Goldbach conjecture.
{{clear}}
{{clear}}
==Notes==
{{Notelist}}


==References==
==References==
Line 162: Line 163:
* [http://www.math.dartmouth.edu/~euler/correspondence/letters/OO0765.pdf Goldbach's original letter to Euler &mdash; PDF format (in German and Latin)]
* [http://www.math.dartmouth.edu/~euler/correspondence/letters/OO0765.pdf Goldbach's original letter to Euler &mdash; PDF format (in German and Latin)]
*[http://primes.utm.edu/glossary/page.php?sort=GoldbachConjecture ''Goldbach's conjecture''], part of Chris Caldwell's [[Prime Pages]].
*[http://primes.utm.edu/glossary/page.php?sort=GoldbachConjecture ''Goldbach's conjecture''], part of Chris Caldwell's [[Prime Pages]].
*[http://www.ieeta.pt/~tos/goldbach.html ''Goldbach conjecture verification''], Tomás Oliveira e Silva's distributed computer search.
*[https://sweet.ua.pt/tos/goldbach.html ''Goldbach conjecture verification''], Tomás Oliveira e Silva's distributed computer search.


{{Prime number conjectures}}
{{Prime number conjectures}}

Revision as of 05:24, 25 June 2025

Template:Short description Template:Infobox mathematical statement

Goldbach's conjecture is one of the oldest and best-known unsolved problems in number theory and all of mathematics. It states that every even natural number greater than 2 is the sum of two prime numbers.

The conjecture has been shown to hold for all integers less than Template:Val, but remains unproven despite considerable effort.

History

Origins

On 7 June 1742, the Prussian mathematician Christian Goldbach wrote a letter to Leonhard Euler (letter XLIII),[1] in which he proposed the following conjecture:

Template:Quote

Goldbach was following the now-abandoned convention of considering 1 to be a prime number,[2] so that a sum of units would be a sum of primes. He then proposed a second conjecture in the margin of his letter, which implies the first:Template:Efn

Template:Quote

Euler replied in a letter dated 30 June 1742[3] and reminded Goldbach of an earlier conversation they had had (Script error: No such module "Lang".), in which Goldbach had remarked that the first of those two conjectures would follow from the statement

Template:Block indent

This is in fact equivalent to his second, marginal conjecture. In the letter dated 30 June 1742, Euler stated:[4][5]

Template:Quote

Similar conjecture by Descartes

René Descartes wrote that "Every even number can be expressed as the sum of at most three primes."[6] The proposition is similar to, but weaker than, Goldbach's conjecture. Paul Erdős said that "Descartes actually discovered this before Goldbach ... but it is better that the conjecture was named for Goldbach because, mathematically speaking, Descartes was infinitely rich and Goldbach was very poor."[7]

Partial results

Goldbach's conjecture involving the sum of two primes is much more difficult than the weak Goldbach conjecture, which says that every odd integer greater than 5 is the sum of three primes. Using Vinogradov's method, Nikolai Chudakov,[8] Johannes van der Corput,[9] and Theodor Estermann[10] showed (1937–1938) that almost all even numbers can be written as the sum of two primes (in the sense that the fraction of even numbers up to some Template:Mvar which can be so written tends towards 1 as Template:Mvar increases). In 1930, Lev Schnirelmann proved that any natural number greater than 1 can be written as the sum of not more than Template:Mvar prime numbers, where Template:Mvar is an effectively computable constant; see Schnirelmann density.[11][12] Schnirelmann's constant is the lowest number Template:Mvar with this property. Schnirelmann himself obtained Template:Math. This result was subsequently enhanced by many authors, such as Olivier Ramaré, who in 1995 showed that every even number Template:Math is in fact the sum of at most 6 primes. The best known result currently stems from the proof of the weak Goldbach conjecture by Harald Helfgott,[13] which directly implies that every even number Template:Math is the sum of at most 4 primes.[14][15]

In 1924, Hardy and Littlewood showed under the assumption of the generalized Riemann hypothesis that the number of even numbers up to Template:Mvar violating the Goldbach conjecture is much less than Template:Math for small Template:Mvar.[16]Template:Fcn

In 1948, using sieve theory methods, Alfréd Rényi showed that every sufficiently large even number can be written as the sum of a prime and an almost prime with at most Template:Mvar factors.[17] Chen Jingrun showed in 1973 using sieve theory that every sufficiently large even number can be written as the sum of either two primes, or a prime and a semiprime (the product of two primes).[18] See Chen's theorem for further information.

In 1975, Hugh Lowell Montgomery and Bob Vaughan showed that "most" even numbers are expressible as the sum of two primes. More precisely, they showed that there exist positive constants Template:Mvar and Template:Mvar such that for all sufficiently large numbers Template:Mvar, every even number less than Template:Mvar is the sum of two primes, with at most Template:Math exceptions. In particular, the set of even integers that are not the sum of two primes has density zero.

In 1951, Yuri Linnik proved the existence of a constant Template:Mvar such that every sufficiently large even number is the sum of two primes and at most Template:Mvar powers of 2. János Pintz and Imre Ruzsa found in 2020 that Template:Math works.[19] Assuming the generalized Riemann hypothesis, Template:Math also works, as shown by Roger Heath-Brown and Jan-Christoph Schlage-Puchta in 2002.[20]

A proof for the weak conjecture was submitted in 2013 by Harald Helfgott to Annals of Mathematics Studies series. Although the article was accepted, Helfgott decided to undertake the major modifications suggested by the referee. Despite several revisions, Helfgott's proof has not yet appeared in a peer-reviewed publication.[21][22][23] The weak conjecture is implied by the Goldbach conjecture, as if Template:Math is a sum of two primes, then Template:Mvar is a sum of three primes. However, the converse implication and thus the Goldbach conjecture would remain unproven if Helfgott's proof is correct.

Computational results

For small values of Template:Mvar, the strong Goldbach conjecture (and hence the weak Goldbach conjecture) can be verified directly. For instance, in 1938, Nils Pipping laboriously verified the conjecture up to Template:Math.[24] With the advent of computers, many more values of Template:Mvar have been checked; T. Oliveira e Silva ran a distributed computer search that has verified the conjecture for Template:Math (and double-checked up to Template:Val) as of 2013. One record from this search is that Template:Val is the smallest number that cannot be written as a sum of two primes where one is smaller than 9781.[25]Template:Fcn

In popular culture

Goldbach's Conjecture (Template:Zh) is the title of the biography of Chinese mathematician and number theorist Chen Jingrun, written by Xu Chi.

The conjecture is a central point in the plot of the 1992 novel Uncle Petros and Goldbach's Conjecture by Greek author Apostolos Doxiadis, in the short story "Sixty Million Trillion Combinations" by Isaac Asimov and also in the 2008 mystery novel No One You Know by Michelle Richmond.[26]

Goldbach's conjecture is part of the plot of the 2007 Spanish film Fermat's Room.

Goldbach's conjecture is featured as the main topic of research of the titular character Marguerite in the 2023 French-Swiss film Marguerite's Theorem.[27]

Formal statement

Each of the three conjectures has a natural analog in terms of the modern definition of a prime, under which 1 is excluded. A modern version of the first conjecture is: Template:Block indent A modern version of the marginal conjecture is:

Template:Block indent

And a modern version of Goldbach's older conjecture of which Euler reminded him is:

Template:Block indent

These modern versions might not be entirely equivalent to the corresponding original statements. For example, if there were an even integer Template:Math larger than 4, for Template:Mvar a prime, that could not be expressed as the sum of two primes in the modern sense, then it would be a counterexample to the modern version of the third conjecture (without being a counterexample to the original version). The modern version is thus probably stronger (but in order to confirm that, one would have to prove that the first version, freely applied to any positive even integer Template:Mvar, could not possibly rule out the existence of such a specific counterexample Template:Mvar). In any case, the modern statements have the same relationships with each other as the older statements did. That is, the second and third modern statements are equivalent, and either implies the first modern statement.

The third modern statement (equivalent to the second) is the form in which the conjecture is usually expressed today. It is also known as the "strong", "even", or "binary" Goldbach conjecture. A weaker form of the second modern statement, known as "Goldbach's weak conjecture", the "odd Goldbach conjecture", or the "ternary Goldbach conjecture", asserts that

Template:Block indent

Heuristic justification

File:Goldbach partitions of the even integers from 4 to 28 300px.png
Sums of two primes at the intersections of three lines

Statistical considerations that focus on the probabilistic distribution of prime numbers present informal evidence in favour of the conjecture (in both the weak and strong forms) for sufficiently large integers: the greater the integer, the more ways there are available for that number to be represented as the sum of two or three other numbers, and the more "likely" it becomes that at least one of these representations consists entirely of primes.

File:Goldbach-1000000.png
Number of ways to write an even number Template:Mvar as the sum of two primes (sequence A002375 in the OEIS)

A very crude version of the heuristic probabilistic argument (for the strong form of the Goldbach conjecture) is as follows. The prime number theorem asserts that an integer Template:Mvar selected at random has roughly a Template:Math chance of being prime. Thus if Template:Mvar is a large even integer and Template:Mvar is a number between 3 and Template:Math, then one might expect the probability of Template:Mvar and Template:Math simultaneously being prime to be Template:Math. If one pursues this heuristic, one might expect the total number of ways to write a large even integer Template:Mvar as the sum of two odd primes to be roughly

m=3n21lnm1ln(nm)n2(lnn)2.

Since Template:Math, this quantity goes to infinity as Template:Mvar increases, and one would expect that every large even integer has not just one representation as the sum of two primes, but in fact very many such representations.

This heuristic argument is actually somewhat inaccurate because it assumes that the events of Template:Mvar and Template:Math being prime are statistically independent of each other. For instance, if Template:Mvar is odd, then Template:Math is also odd, and if Template:Mvar is even, then Template:Math is even, a non-trivial relation because, besides the number 2, only odd numbers can be prime. Similarly, if Template:Mvar is divisible by 3, and Template:Mvar was already a prime other than 3, then Template:Math would also be coprime to 3 and thus be slightly more likely to be prime than a general number. Pursuing this type of analysis more carefully, G. H. Hardy and John Edensor Littlewood in 1923 conjectured (as part of their Hardy–Littlewood prime tuple conjecture) that for any fixed Template:Math, the number of representations of a large integer Template:Mvar as the sum of Template:Mvar primes Template:Math with Template:Math should be asymptotically equal to

(ppγc,p(n)(p1)c)2x1xc:x1++xc=ndx1dxc1lnx1lnxc,

where the product is over all primes Template:Mvar, and Template:Math is the number of solutions to the equation Template:Math in modular arithmetic, subject to the constraints Template:Math. This formula has been rigorously proven to be asymptotically valid for Template:Math from the work of Ivan Matveevich Vinogradov, but is still only a conjecture when Template:Math.Script error: No such module "Unsubst". In the latter case, the above formula simplifies to 0 when Template:Mvar is odd, and to

2Π2(pn;p3p1p2)2ndx(lnx)22Π2(pn;p3p1p2)n(lnn)2

when Template:Mvar is even, where Template:Math is Hardy–Littlewood's twin prime constant

Π2:=pprime3(11(p1)2)0.660161815846869573927812110014

This is sometimes known as the extended Goldbach conjecture. The strong Goldbach conjecture is in fact very similar to the twin prime conjecture, and the two conjectures are believed to be of roughly comparable difficulty.

Goldbach partition function

File:Goldbachs comet.gif
Goldbach's comet; red, blue and green points correspond respectively the values 0, 1 and 2 modulo 3 of the number.

The Template:Vanchor function is the function that associates to each even integer the number of ways it can be decomposed into a sum of two primes. Its graph looks like a comet and is therefore called Goldbach's comet.[28]

Goldbach's comet suggests tight upper and lower bounds on the number of representations of an even number as the sum of two primes, and also that the number of these representations depend strongly on the value modulo 3 of the number.

Related problems

Although Goldbach's conjecture implies that every positive integer greater than one can be written as a sum of at most three primes, it is not always possible to find such a sum using a greedy algorithm that uses the largest possible prime at each step. The Pillai sequence tracks the numbers requiring the largest number of primes in their greedy representations.[29]

Similar problems to Goldbach's conjecture exist in which primes are replaced by other particular sets of numbers, such as the squares:

Goldbach's conjecture is used when studying computational complexity.[35] The connection is made through the Busy Beaver function, where BB(n) is the maximum number of steps taken by any n state Turing machine that halts. There is a 27-state Turing machine that halts if and only if Goldbach's conjecture is false.[35] Hence if BB(27) was known, and the Turing machine did not stop in that number of steps, it would be known to run forever and hence no counterexamples exist (which proves the conjecture true). This is a completely impractical way to settle the conjecture; instead it is used to suggest that BB(27) will be very hard to compute, at least as difficult as settling the Goldbach conjecture.

Notes

Template:Notelist

References

Template:Reflist

Further reading

External links

Template:Prime number conjectures Template:Authority control

  1. Script error: No such module "citation/CS1".
  2. Script error: No such module "Template wrapper".
  3. Script error: No such module "citation/CS1".
  4. Script error: No such module "citation/CS1".
  5. Script error: No such module "citation/CS1".
  6. Pintz, János. "On a conjecture of Descartes". ELKH Rényi Mathematical Institute of the Hungarian Academy of Sciences. Retrieved 20 June 2025.
  7. Script error: No such module "citation/CS1".
  8. Script error: No such module "Citation/CS1".
  9. Script error: No such module "Citation/CS1".
  10. Script error: No such module "Citation/CS1".
  11. Schnirelmann, L. G. (1930). 'On the additive properties of numbers". First published in Proceedings of the Don Polytechnic Institute in Novocherkassk (in Russian), vol 14 (1930), pp. 3–27, and reprinted in Uspekhi Matematicheskikh Nauk (in Russian), 1939, no. 6, 9–25.
  12. Schnirelmann, L. G. (1933). First published as "Über additive Eigenschaften von Zahlen". In Mathematische Annalen (in German), vol. 107 (1933), 649–690, and reprinted as "On the additive properties of numbers" in Uspekhi Matematicheskikh Nauk (in Russian), 1940, no. 7, 7–46.
  13. Script error: No such module "citation/CS1".
  14. Script error: No such module "Citation/CS1".
  15. Script error: No such module "citation/CS1".
  16. See, for example, A new explicit formula in the additive theory of primes with applications I. The explicit formula for the Goldbach and Generalized Twin Prime Problems by Janos Pintz.
  17. Script error: No such module "Citation/CS1".
  18. Script error: No such module "Citation/CS1".
  19. Script error: No such module "Citation/CS1".
  20. Script error: No such module "Citation/CS1".
  21. Script error: No such module "citation/CS1".
  22. Script error: No such module "citation/CS1".
  23. Script error: No such module "citation/CS1".
  24. Pipping, Nils (1890–1982). "Die Goldbachsche Vermutung und der Goldbach-Vinogradowsche Satz". Acta Academiae Aboensis, Mathematica et physica 11, 4–25, 1938.
  25. Tomás Oliveira e Silva, "Goldbach conjecture verification". Retrieved 20 April 2024.
  26. Script error: No such module "citation/CS1".
  27. Morain, Odile. Le Théorème de Marguerite. franceinfo:culture
  28. Script error: No such module "Citation/CS1".
  29. Template:Cite OEIS
  30. Mathematics Magazine, 66:1 (1993): 45–47.
  31. Script error: No such module "Citation/CS1".
  32. Script error: No such module "Citation/CS1".
  33. Script error: No such module "citation/CS1".
  34. Template:Cite OEIS
  35. a b Script error: No such module "citation/CS1".
Retrieved from "http://debianws.lexgopc.com/wiki143/index.php?title=Goldbach%27s_conjecture&oldid=730724"