Wieferich prime: Difference between revisions

Wieferich prime
Named after	Arthur Wieferich
Publication year	1909
Author of publication	Wieferich, A.
No. of known terms	2
Subsequence of	Crandall numbers; Wieferich numbers; near-Wieferich primes
First terms	1093, 3511
Largest known term	3511
OEIS index	A001220

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In number theory, a Wieferich prime is a prime number p such that p² divides 2^p − 1 − 1,^[3] therefore connecting these primes with Fermat's little theorem, which states that every odd prime p divides 2^p − 1 − 1. Wieferich primes were first described by Arthur Wieferich in 1909 in works pertaining to Fermat's last theorem, at which time both theorems were already well known to mathematicians.^[4]^[5]

Despite a number of extensive searches, the only known Wieferich primes to date are 1093 and 3511 (sequence A001220 in the OEIS).

Properties

Connection with Fermat's last theorem

The following theorem connecting Wieferich primes and Fermat's last theorem was proven by Wieferich in 1909:^[6]

Let p be prime, and let x, y, z be integers such that x^p + y^p + z^p = 0. Furthermore, assume that p does not divide the product xyz. Then p is a Wieferich prime.

The above case (where p does not divide any of x, y or z) is commonly known as the first case of Fermat's Last Theorem (FLTI).^[7]^[8] In 1910, Mirimanoff expanded^[9] the theorem by showing that, if the preconditions of the theorem hold true for some prime p, then p² must also divide 3^p − 1 − 1. Morishima further proved that p² must actually divide m^p − 1 − 1 for every prime m ≤ 31.^[10] Granville and Monagan extended the proof to all m ≤ 89.^[11]

Connection with the abc conjecture

A non-Wieferich prime is a prime p satisfying 2^p − 1 ≢ 1 (mod p²). Silverman showed in 1988 that if the abc conjecture holds, then there exist infinitely many non-Wieferich primes.^[12] Numerical evidence suggests that very few of the prime numbers in a given interval are Wieferich primes. A proof of the abc conjecture would not automatically prove that there are only finitely many Wieferich primes, since the set of Wieferich primes and the set of non-Wieferich primes could possibly both be infinite and the finiteness or infiniteness of the set of Wieferich primes would have to be proven separately.

Connection with Mersenne primes and Fermat primes

It is known that the nth Mersenne number M_n = 2ⁿ − 1 is prime only if n is prime. Fermat's little theorem implies that if p > 2 is prime, then M_p−1 (= 2^p − 1 − 1) is always divisible by p. Since Mersenne numbers of prime indices M_p and M_q are co-prime,

A prime divisor p of M_q, where q is prime, is a Wieferich prime if and only if p² divides M_q.^[13]

Thus, a Mersenne prime cannot also be a Wieferich prime. A notable open problem is to determine whether or not all Mersenne numbers of prime index are square-free. If a Mersenne number M_q is not square-free, i.e., there exists a prime p for which p² divides M_q, then p is a Wieferich prime. Therefore, if there are only finitely many Wieferich primes, then there will be at most finitely many Mersenne numbers that are not square-free. It was observed that M₁₀₉₂ is divisible by 1093² and M₃₅₁₀ is divisible by 3511².^[14]

Similarly, if p is prime and p² divides some Fermat number F_n = 2^2ⁿ + 1, then p must be a Wieferich prime.^[15]

Other properties

Johnson observed^[16] that the two known Wieferich primes are one greater than numbers with periodic binary expansions ( $1092=010001000100_{2}$ ; $3510=110110110110_{2}$ ). The Wieferich@Home project searches for Wieferich primes by testing numbers that are one greater than a number with a periodic binary expansion, but up to a total binary expansion length of 3500 and up to a period length of 24 it has not found a new Wieferich prime.^[17]

If p is a Wieferich prime, then 2^p ≡ 2 (mod p²) and thus 2^p² ≡ 2 (mod p²).

History and search status

Unsolved problem in mathematics:

Are there any Wieferich primes other than 1093 and 3511?

(more unsolved problems in mathematics)

In 1902 W. F. Meyer proved a theorem about solutions of the congruence a^{p − 1} ≡ 1 (mod p^r). ^[18] Later in that decade Arthur Wieferich showed specifically that if the First Case of Fermat's Last Theorem has solutions for an odd prime exponent, then that prime must satisfy that congruence for a = 2. In other words, if there exist solutions to x^p + y^p + z^p = 0 in integers x, y, z and p an odd prime with p $\nmid$ xyz, then p satisfies 2^p-1 ≡ 1 (mod p²).

The only known Wieferich primes 1093 and 3511 were found by W. Meissner in 1913^[19] and N. G. W. H. Beeger in 1922,^[20] respectively. Around 1980, Lehmer was able to reach the search limit of 6×10⁹.^[21] This limit was extended above 2.5×10¹⁵ in 2006.^[22] It is now known, that if any other Wieferich primes exist, they must be greater than 6.7×10¹⁵.^[23] The search for new Wieferich primes is currently performed by the distributed computing project Wieferich@Home.

It has been conjectured that only finitely many Wieferich primes exist.^[3] It has also been conjectured (as for Wilson primes) that infinitely many Wieferich primes exist, and that the number of Wieferich primes below x is approximately log log x, which is a heuristic result that follows from the plausible assumption that for a prime p, the (p − 1)-th degree roots of unity modulo p² are uniformly distributed in the multiplicative group of integers modulo p².^[24]

Generalizations

A prime p satisfying the congruence 2^(p−1)/2 ≡ ±1 + Ap (mod p²) with small |A| is commonly called a near-Wieferich prime (sequence A195988 in the OEIS).^[24]^[25] Near-Wieferich primes with A = 0 represent Wieferich primes. Recent searches, in addition to their primary search for Wieferich primes, also tried to find near-Wieferich primes.^[23]^[26] The following table lists all near-Wieferich primes with |A| ≤ 10 up to 3×10¹⁵. This search bound was reached in 2006 in a search effort by P. Carlisle, R. Crandall and M. Rodenkirch.^[22]^[27]

p	1 or −1	A
1093	+1	0
3511	+1	0
46262476201	+1	+5
47004625957	−1	+1
58481216789	−1	+5
76843523891	−1	+1
1180032105761	+1	−6
12456646902457	+1	+2
134257821895921	+1	+10
339258218134349	−1	+2
2276306935816523	−1	−3

Dorais and Klyve^[23] used a different definition of a near-Wieferich prime, defining it as a prime p with small value of $\left|{\frac {\omega (p)}{p}}\right|$ where $\omega (p)={\frac {2^{p-1}-1}{p}}\,{\bmod {\,}}p$ is the Fermat quotient of p modulo p (the modulo operation here gives the residue with the smallest absolute value). The following table lists all primes p ≤ 6.7 × 10¹⁵ with $\left|{\frac {\omega (p)}{p}}\right|\leq 10^{-14}$ .

p	$\omega (p)$	$\left\|{\frac {\omega (p)}{p}}\right\|\times 10^{14}$
1093	0	0
3511	0	0
2276306935816523	+6	0.264
3167939147662997	−17	0.537
3723113065138349	−36	0.967
5131427559624857	−36	0.702
5294488110626977	−31	0.586
6517506365514181	+58	0.890

A Wieferich prime base a is a prime p that satisfies
a^p − 1 ≡ 1 (mod p²).^[28]

Such a prime cannot divide a, since then it would also divide 1. For the known Wieferich primes base a with small prime values of a, see Fermat quotient.

A Wieferich pair is a pair of primes p and q that satisfy
p^{q − 1} ≡ 1 (mod q²) and q^{p − 1} ≡ 1 (mod p²)

so that a Wieferich prime p ≡ 1 (mod 4) will form such a pair (p, 2): the only known instance in this case is p = 1093. There are 6 known Wieferich pairs.^[29]

A Wieferich number is an odd integer w ≥ 3 satisfying the congruence 2^φ(w) ≡ 1 (mod w). If w is prime, then it is a Wieferich prime. It can be shown that if there are only finitely many Wieferich primes, then there are only finitely many Wieferich numbers. In particular it was shown, that if only the two Wieferich primes 1093 and 3511 exist, then there exist exactly 104 Wieferich numbers, which matches the number of Wieferich numbers currently known.^[2]

References

^ Franco, Z.; Pomerance, C. (1995), "On a conjecture of Crandall concerning the qx+1 problem" (PDF), Math. Of Comput., 64 (211), American Mathematical Society: 1333–1336, doi:10.2307/2153499.
^ ^a ^b Banks, W. D.; Luca, F.; Shparlinski, I. E. (2007), "Estimates for Wieferich numbers" (PDF), The Ramanujan Journal, 14 (3), Springer: 361–378, doi:10.1007/s11139-007-9030-z.
^ ^a ^b The Prime Glossary: Wieferich prime
^ Israel Kleiner (2000), "From Fermat to Wiles: Fermat's Last Theorem Becomes a Theorem" (PDF), Elem. Math., 55: 21.Template:WebCite
^ Leonhard Euler (1736), "Theorematum quorundam ad numeros primos spectantium demonstratio", Novi Comm. Acad. Sci. Petropol., 8: 33–37.
^ Wieferich, A. (1909), "Zum letzten Fermat'schen Theorem", Journal für die reine und angewandte Mathematik, 136 (136): 293–302, doi:10.1515/crll.1909.136.293.
^ Coppersmith, D. (1990), "Fermat's Last Theorem (Case I) and the Wieferich Criterion" (PDF), Math. Comp., 54 (190), AMS: 895–902, JSTOR 2008518.
^ Cikánek, P. (1994), "A Special Extension of Wieferich's Criterion" (PDF), Math. Comp., 62 (206), AMS: 923–930, JSTOR 3562296.
^ Mirimanoff, D. (1910), "Sur le dernier théorème de Fermat", Comptes rendus hebdomadaires des séances de l'Académie des Sciences, 150: 293–206.
^ Morishima, T. (1935), "Ueber die Fermatsche Vermutung. XI", Jap. J. Math. (in German), 11: 241–252
^ Granville, A.; Monagan, M. B. (1988), "The First Case of Fermat's Last Theorem is true for all prime exponents up to 714,591,416,091,389" (PDF), Transactions of the American Mathematical Society, 306 (1): 329–359.
^ Charles, D. X. On Wieferich primes
^ Mersenne Primes: Conjectures and Unsolved Problems
^ Kures, M. Wieferich primes and Mersenne primes
^ Ribenboim, Paulo (1991), The little book of big primes, New York: Springer, p. 64, ISBN 038797508X
^ Wells Johnson (1977), "On the nonvanishing of Fermat quotients (mod p)", J. Reine angew. Math., 292: 196–200
^ Dobeš, Jan; Kureš, Miroslav (2010), "Search for Wieferich primes through the use of periodic binary strings", Serdica Journal of Computing, 4: 293–300, ISSN 1312-6555.
^ Keller, Richstein (2004), p. 930
^ Meissner, W. (1913), "Über die Teilbarkeit von 2^p − 2 durch das Quadrat der Primzahl p=1093", Sitzungsber. D. Königl. Preuss. Akad. D. Wiss., Zweiter Halbband. Juli bis Dezember, Berlin: 663–667
^ Beeger, N. G. W. H. (1922), "On a new case of the congruence 2^{p − 1} ≡ 1 (p²)", Messenger of Mathematics, 51: 149–150Template:WebCite
^ Lehmer, D. H. (1981-01), "On Fermat's Quotient, Base Two" (PDF), Math of Comp, 36 (153), AMS: 289–290, retrieved 2011-04-22. {{citation}}: Check date values in: |date= (help)
^ ^a ^b Ribenboim, Paulo (2004), Die Welt der Primzahlen: Geheimnisse und Rekorde, New York: Springer, p. 237, ISBN 3540342834
^ ^a ^b ^c Dorais, F. G. (2011). "A Wieferich Prime Search Up to 6.7×10¹⁵" (PDF). Journal of Integer Sequences. 14 (9). Journal of Integer Sequences. Retrieved 23-10-2011. {{cite journal}}: Check date values in: |accessdate= (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)
^ ^a ^b Crandall, Richard E.; Dilcher, Karl; Pomerance, Carl (1997), "A search for Wieferich and Wilson primes" (PDF), Math. Comput., 66 (217): 433–449, doi:10.1090/S0025-5718-97-00791-6.
^ Joshua Knauer; Jörg Richstein (2005), "The continuing search for Wieferich primes" (PDF), Math. Comp., 74 (251): 1559–1563, doi:10.1090/S0025-5718-05-01723-0.{{citation}}: CS1 maint: multiple names: authors list (link)
^ About project Wieferich@Home
^ Ribenboim, Paulo (2000), My numbers, my friends: popular lectures on number theory, New York: Springer, pp. 213–229, ISBN 9780387989112
^ Wilfrid Keller; Jörg Richstein (2005), "Solutions of the congruence a^p−1 ≡ 1 (mod p^r)" (PDF), Math. Comp., 74 (250): 927–936, doi:10.1090/S0025-5718-04-01666-7.{{citation}}: CS1 maint: multiple names: authors list (link)
^ Weisstein, Eric W. "Double Wieferich Prime Pair". MathWorld.

External links

[1] Franco, Z.; Pomerance, C. (1995), "On a conjecture of Crandall concerning the qx+1 problem" (PDF), Math. Of Comput., 64 (211), American Mathematical Society: 1333–1336, doi:10.2307/2153499.

[Banks,_Luca-2] Banks, W. D.; Luca, F.; Shparlinski, I. E. (2007), "Estimates for Wieferich numbers" (PDF), The Ramanujan Journal, 14 (3), Springer: 361–378, doi:10.1007/s11139-007-9030-z.

[The_Prime_Glossary-3] The Prime Glossary: Wieferich prime

[Kleiner-4] Israel Kleiner (2000), "From Fermat to Wiles: Fermat's Last Theorem Becomes a Theorem" (PDF), Elem. Math., 55: 21.Template:WebCite

[Euler-5] Leonhard Euler (1736), "Theorematum quorundam ad numeros primos spectantium demonstratio", Novi Comm. Acad. Sci. Petropol., 8: 33–37.

[6] Wieferich, A. (1909), "Zum letzten Fermat'schen Theorem", Journal für die reine und angewandte Mathematik, 136 (136): 293–302, doi:10.1515/crll.1909.136.293.

[7] Coppersmith, D. (1990), "Fermat's Last Theorem (Case I) and the Wieferich Criterion" (PDF), Math. Comp., 54 (190), AMS: 895–902, JSTOR 2008518.

[8] Cikánek, P. (1994), "A Special Extension of Wieferich's Criterion" (PDF), Math. Comp., 62 (206), AMS: 923–930, JSTOR 3562296.

[9] Mirimanoff, D. (1910), "Sur le dernier théorème de Fermat", Comptes rendus hebdomadaires des séances de l'Académie des Sciences, 150: 293–206.

[10] Morishima, T. (1935), "Ueber die Fermatsche Vermutung. XI", Jap. J. Math. (in German), 11: 241–252

[11] Granville, A.; Monagan, M. B. (1988), "The First Case of Fermat's Last Theorem is true for all prime exponents up to 714,591,416,091,389" (PDF), Transactions of the American Mathematical Society, 306 (1): 329–359.

[12] Charles, D. X. On Wieferich primes

[13] Mersenne Primes: Conjectures and Unsolved Problems

[14] Kures, M. Wieferich primes and Mersenne primes

[15] Ribenboim, Paulo (1991), The little book of big primes, New York: Springer, p. 64, ISBN 038797508X

[John-16] Wells Johnson (1977), "On the nonvanishing of Fermat quotients (mod p)", J. Reine angew. Math., 292: 196–200

[DoKu-17] Dobeš, Jan; Kureš, Miroslav (2010), "Search for Wieferich primes through the use of periodic binary strings", Serdica Journal of Computing, 4: 293–300, ISSN 1312-6555.

[18] Keller, Richstein (2004), p. 930

[19] Meissner, W. (1913), "Über die Teilbarkeit von 2^p − 2 durch das Quadrat der Primzahl p=1093", Sitzungsber. D. Königl. Preuss. Akad. D. Wiss., Zweiter Halbband. Juli bis Dezember, Berlin: 663–667

[20] Beeger, N. G. W. H. (1922), "On a new case of the congruence 2^{p − 1} ≡ 1 (p²)", Messenger of Mathematics, 51: 149–150Template:WebCite

[21] Lehmer, D. H. (1981-01), "On Fermat's Quotient, Base Two" (PDF), Math of Comp, 36 (153), AMS: 289–290, retrieved 2011-04-22. {{citation}}: Check date values in: |date= (help)

[Ribenboim,_2004-22] Ribenboim, Paulo (2004), Die Welt der Primzahlen: Geheimnisse und Rekorde, New York: Springer, p. 237, ISBN 3540342834

[Dorais-23] Dorais, F. G. (2011). "A Wieferich Prime Search Up to 6.7×10¹⁵" (PDF). Journal of Integer Sequences. 14 (9). Journal of Integer Sequences. Retrieved 23-10-2011. {{cite journal}}: Check date values in: |accessdate= (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)

[Crandall-24] Crandall, Richard E.; Dilcher, Karl; Pomerance, Carl (1997), "A search for Wieferich and Wilson primes" (PDF), Math. Comput., 66 (217): 433–449, doi:10.1090/S0025-5718-97-00791-6.

[Knauer-25] Joshua Knauer; Jörg Richstein (2005), "The continuing search for Wieferich primes" (PDF), Math. Comp., 74 (251): 1559–1563, doi:10.1090/S0025-5718-05-01723-0.{{citation}}: CS1 maint: multiple names: authors list (link)

[elmath-26] About project Wieferich@Home

[27] Ribenboim, Paulo (2000), My numbers, my friends: popular lectures on number theory, New York: Springer, pp. 213–229, ISBN 9780387989112

[Solutions-28] Wilfrid Keller; Jörg Richstein (2005), "Solutions of the congruence a^p−1 ≡ 1 (mod p^r)" (PDF), Math. Comp., 74 (250): 927–936, doi:10.1090/S0025-5718-04-01666-7.{{citation}}: CS1 maint: multiple names: authors list (link)

[29] Weisstein, Eric W. "Double Wieferich Prime Pair". MathWorld.

[1]

@@ Line 45: / Line 45: @@
 {{unsolved|mathematics|Are there any Wieferich primes other than 1093 and 3511?}}
 In 1902 [[W. F. Meyer]] proved a theorem about solutions of the congruence a<sup>''p'' &minus; 1</sup> &equiv; 1 (mod ''p''<sup>r</sup>). <ref>Keller, Richstein (2004), p. 930</ref> Later in that decade [[Arthur Wieferich]] showed specifically that if the [[First Case of Fermat's Last Theorem]] has solutions for an odd prime exponent, then that prime must satisfy that congruence for a = 2. In other words, if there exist solutions to ''x''<sup>''p''</sup> + ''y''<sup>''p''</sup> + ''z''<sup>''p''</sup> = 0 in integers ''x'', ''y'', ''z'' and ''p'' an [[odd prime]] with ''p'' \nmid ''xyz'', then ''p'' satisfies 2<sup>''p-1''</sup> &equiv; 1 (mod ''p''<sup>2</sup>).
 The only known Wieferich primes 1093 and 3511 were found by [[Waldemar Meissner|W. Meissner]] in 1913<ref>{{citation | first=W. |last=Meissner |title=Über die Teilbarkeit von 2<sup>''p''</sup> &minus; 2 durch das Quadrat der Primzahl ''p''=1093 | journal=Sitzungsber. D. Königl. Preuss. Akad. D. Wiss. | volume=Zweiter Halbband. Juli bis Dezember | place=Berlin | year=1913 | pages=663–667 }}</ref> and [[N. G. W. H. Beeger]] in 1922,<ref>{{citation | first=N. G. W. H. |last=Beeger | authorlink=N. G. W. H. Beeger | title=On a new case of the congruence 2<sup>''p'' &minus; 1</sup> ≡ 1 (''p''<sup>2</sup>) | journal=[[Messenger of Mathematics]] | volume=51 | year=1922 | pages=149–150 |url=http://www.archive.org/stream/messengerofmathe5051cambuoft#page/148/mode/2up}}{{WebCite|url=http://www.webcitation.org/5zo7d2jde}}</ref> respectively. Around 1980, Lehmer was able to reach the search limit of 6{{e|9}}.<ref>{{Citation | last = Lehmer  | first = D. H. | authorlink = Derrick Henry Lehmer | title = On Fermat's Quotient, Base Two | journal = Math of Comp | volume = 36 | issue = 153 | pages = 289–290 | publisher = [[American Mathematical Society|AMS]] | date = 1981-01 | url = http://www.ams.org/journals/mcom/1981-36-153/S0025-5718-1981-0595064-5/S0025-5718-1981-0595064-5.pdf | accessdate = 2011-04-22 | postscript = .}}</ref> This limit was extended above 2.5{{e|15}} in 2006.<ref name="Ribenboim, 2004"></ref> It is now known, that if any other Wieferich primes exist, they must be greater than 6.7{{e|15}}.<ref name=Dorais>{{cite journal | last = Dorais | first = F. G. | authorlink = François G. Dorais | coauthors = Klyve, D. | title = A Wieferich Prime Search Up to 6.7{{e|15}}

v t e Prime number classes
By formula	Fermat ( $2 2 n + 1$ ) Mersenne ( $2 p - 1$ ) Double Mersenne ( $2 2 p -1 - 1$ ) Wagstaff $(2 p + 1)/3$ Proth ( $k \cdot2 n + 1$ ) Factorial ( $n! \pm 1$ ) Primorial ( $p n # \pm 1$ ) Euclid ( $p n # + 1$ ) Pythagorean ( $4 n + 1$ ) Pierpont ( $2 m \cdot3 n + 1$ ) Quartan ( $x 4 + y 4$ ) Solinas ( $2 m \pm 2 n \pm 1$ ) Cullen ( $n \cdot2 n + 1$ ) Woodall ( $n \cdot2 n - 1$ ) Cuban ( $x 3 - y 3)/(x - y$ ) Leyland ( $x y + y x$ ) Thabit ( $3\cdot2 n - 1$ ) Williams ( $(b -1)\cdot b n - 1$ ) Mills ( $⌊ A 3 n ⌋$ )
By integer sequence	Fibonacci Lucas Pell Newman–Shanks–Williams Perrin
By property	Wieferich (pair) Wall–Sun–Sun Wolstenholme Wilson Lucky Fortunate Ramanujan Pillai Regular Strong Stern Supersingular (elliptic curve) Supersingular (moonshine theory) Good Super Higgs Highly cototient Unique
Base-dependent	Palindromic Emirp Repunit $(10 n - 1)/9$ Permutable Circular Truncatable Minimal Delicate Primeval Full reptend Unique Happy Self Smarandache–Wellin Strobogrammatic Dihedral Tetradic
Patterns	Twin ( $p, p + 2$ ) Bi-twin chain ( $n \pm 1, 2 n \pm 1, 4 n \pm 1, \dots$ ) Triplet ( $p, p + 2 or p + 4, p + 6$ ) Quadruplet ( $p, p + 2, p + 6, p + 8$ ) k-tuple Cousin ( $p, p + 4$ ) Sexy ( $p, p + 6$ ) Chen Sophie Germain/Safe ( $p, 2 p + 1$ ) Cunningham ( $p, 2 p \pm 1, 4 p \pm 3, 8 p \pm 7, ...$ ) Arithmetic progression ( $p + a\cdotn, n = 0, 1, 2, 3, ...$ ) Balanced ( $consecutive p - n, p, p + n$ )
By size	Mega (1,000,000+ digits) Largest known list
Complex numbers	Eisenstein prime Gaussian prime
Composite numbers	Pseudoprime Catalan Elliptic Euler Euler–Jacobi Fermat Frobenius Lucas Perrin Somer–Lucas Strong Carmichael number Almost prime Semiprime Sphenic number Interprime Pernicious
Related topics	Probable prime Industrial-grade prime Illegal prime Formula for primes Prime gap
First 60 primes	2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199 211 223 227 229 233 239 241 251 257 263 269 271 277 281
List of prime numbers