Search: id:A001122 Results 1-1 of 1 results found. %I A001122 M2473 N0981 %S A001122 3,5,11,13,19,29,37,53,59,61,67,83,101,107,131,139,149,163,173,179,181, %T A001122 197,211,227,269,293,317,347,349,373,379,389,419,421,443,461,467,491,509, %U A001122 523,541,547,557,563,587,613,619,653,659,661,677,701,709,757,773,787,797 %N A001122 Primes with primitive root 2. %C A001122 Artin conjectured that this sequence is infinite. %C A001122 Conjecture : sequence contains infinitely many pairs of twin primes. - Benoit Cloitre (benoit7848c(AT)orange.fr), May 08 2003 %C A001122 Pieter Moree writes (Oct 20 2004): Assuming the Generalized Riemann Hypothesis it can be shown that the density of primes p such that a prescribed integer g has order (p-1)/t, with t fixed exists and, moreover, it can be computed. This density will be a rational number times the so called Artin constant. For 2 and 10 the density of primitive roots is A, the Artin constant itself. %C A001122 It seems that this sequence consists of A050229 \ {1,2}. %C A001122 Primes p such that 1/p, when written in base 2, has period p-1, which is the greatest period possible for any integer. %D A001122 N. J. A. Sloane and Simon Plouffe, The Encyclopedia of Integer Sequences, Academic Press, 1995 (includes this sequence). %D A001122 N. J. A. Sloane, A Handbook of Integer Sequences, Academic Press, 1973 (includes this sequence). %D A001122 M. Abramowitz and I. A. Stegun, eds., Handbook of Mathematical Functions, National Bureau of Standards Applied Math. Series 55, 1964 (and various reprintings), p. 864. %D A001122 E. Bach and J. O. Shallit, Algorithmic Number Theory, I; see p. 221. %D A001122 J. H. Conway and R. K. Guy, The Book of Numbers, Copernicus Press, New York, 1996; see p. 169. %D A001122 R. Gupta and M. R. Murty: A remark on Artin's conjecture, Invent. Math. 78 (1984) 127-230. %D A001122 C. Hooley: On Artin's conjecture, J. Reine Angewandte Math., 225 (1967) 209-220. %D A001122 M. Kraitchik, Recherches sur la Th\'{e}orie des Nombres. Gauthiers-Villars, Paris, Vol. 1, 1924, Vol. 2, 1929, see Vol. 1, p. 56. %D A001122 Lehmer, D. H. and Lehmer, Emma; Heuristics, anyone? in Studies in mathematical analysis and related topics, pp. 202-210, Stanford Univ. Press, Stanford, Calif., 1962. %D A001122 F. Pillichshammer, Bounds for the quality parameter of digital shift nets over Z_2, Finite Fields Applic., 8 (2002), 444-454. %D A001122 D. Shanks, Solved and Unsolved Problems in Number Theory, 2nd. ed., Chelsea, 1978, p. 81. %H A001122 T. D. Noe, Table of n, a(n) for n = 1..1000 %H A001122 Joerg Arndt, Fxtbook %H A001122 M. Abramowitz and I. A. Stegun, eds., Handbook of Mathematical Functions, National Bureau of Standards, Applied Math. Series 55, Tenth Printing, 1972 [alternative scanned copy]. %H A001122 Index entries for sequences related to Artin's conjecture %H A001122 Index entries for primes by primitive root %H A001122 P. Moree, Artin's primitive root conjecture-a survey %H A001122 D. Williams, Primitive Roots(Check) %t A001122 (* first do *) Needs["NumberTheory`NumberTheoryFunctions`"] (* then *) Select[Prime[ Range[137]], PrimitiveRoot[ # ] == 2 & ] %t A001122 (* first load *) << NumberTheory`NumberTheoryFunctions` (* then *) Select[ Prime@Range@200, PrimitiveRoot@# == 2 &] (from Robert G. Wilson v (rgwv(at)rgwv.com), May 11 2001) %t A001122 pr=2; Select[Prime[Range[200]], MultiplicativeOrder[pr, # ] == #-1 &] %o A001122 (PARI) forprime(p=3,1000, if(znprimroot(p)==2,print(p))). %o A001122 (PARI) { n=0; forprime (p=3, 99999, if (znprimroot(p)==2, n++; write("b001122.txt", n, " ", p); if (n>=1000, break) ) ) } [From Harry J. Smith (hjsmithh(AT)sbcglobal.net), Jun 14 2009] %Y A001122 Cf. A001123, A001913, A050229. %Y A001122 Sequence in context: A059644 A059646 A003629 this_sequence A152871 A156221 A078971 %Y A001122 Adjacent sequences: A001119 A001120 A001121 this_sequence A001123 A001124 A001125 %K A001122 nonn,easy,nice %O A001122 1,1 %A A001122 N. J. A. Sloane (njas(AT)research.att.com). Search completed in 0.002 seconds