In mathematics, the Mersenne conjectures concern the characterization of a kind of prime numbers called Mersenne primes, meaning prime numbers that are a power of two minus one.
The original, called Mersenne's conjecture, was a statement by Marin Mersenne in his Cogitata Physico-Mathematica (1644; see e.g. Dickson 1919) that the numbers
2n-1
2n-1
While Mersenne's original conjecture is false, it may have led to the New Mersenne conjecture.
The New Mersenne conjecture or Bateman, Selfridge and Wagstaff conjecture (Bateman et al. 1989) states that for any odd natural number p, if any two of the following conditions hold, then so does the third:
If p is an odd composite number, then 2p − 1 and (2p + 1)/3 are both composite. Therefore it is only necessary to test primes to verify the truth of the conjecture.
Currently, there are nine known numbers for which all three conditions hold: 3, 5, 7, 13, 17, 19, 31, 61, 127 . Bateman et al. expected that no number greater than 127 satisfies all three conditions, and showed that heuristically no greater number would even satisfy two conditions, which would make the New Mersenne Conjecture trivially true.
, all the Mersenne primes up to 257885161 − 1 are known, and for none of these does the third condition hold except for the ones just mentioned.[2] [3] Primes which satisfy at least one condition are
2, 3, 5, 7, 11, 13, 17, 19, 23, 31, 43, 61, 67, 79, 89, 101, 107, 127, 167, 191, 199, 257, 313, 347, 521, 607, 701, 1021, 1279, 1709, 2203, 2281, 2617, 3217, 3539, 4093, 4099, 4253, 4423, 5807, 8191, 9689, 9941, ...
Note that the two primes for which the original Mersenne conjecture is false (67 and 257) satisfy the first condition of the new conjecture (67 = 26 + 3, 257 = 28 + 1), but not the other two. 89 and 107, which were missed by Mersenne, satisfy the second condition but not the other two. Mersenne may have thought that 2p − 1 is prime only if p = 2k ± 1 or p = 4k ± 3 for some natural number k, but if he thought it was "if and only if" he would have included 61.
| 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 | |
| 283 | 293 | 307 | 311 | 313 | 317 | 331 | 337 | 347 | 349 | |
| 353 | 359 | 367 | 373 | 379 | 383 | 389 | 397 | 401 | 409 | |
| 419 | 421 | 431 | 433 | 439 | 443 | 449 | 457 | 461 | 463 | |
| 467 | 479 | 487 | 491 | 499 | 503 | 509 | 521 | 523 | 541 |
| Red: p is of the form 2n±1 or 4n±3 | Cyan background: 2p−1 is prime | Italics: (2p+1)/3 is prime | Bold: p satisfies at least one condition |
The New Mersenne conjecture can be thought of as an attempt to salvage the centuries-old Mersenne's conjecture, which is false. However, according to Robert D. Silverman, John Selfridge agreed that the New Mersenne conjecture is "obviously true" as it was chosen to fit the known data and counter-examples beyond those cases are exceedingly unlikely. It may be regarded more as a curious observation than as an open question in need of proving.
Prime Pages shows that the New Mersenne conjecture is true for all integers less than or equal to 30402457[2] by systematically listing all primes for which it is already known that one of the conditions holds.
Lenstra, Pomerance, and Wagstaff have conjectured that there are infinitely many Mersenne primes, and, more precisely, that the number of Mersenne primes less than x is asymptotically approximated by
| \gamma ⋅ log | |
| e | |
| 2 |
log2(x),
where γ is the Euler–Mascheroni constant. In other words, the number of Mersenne primes with exponent p less than y is asymptotically
| \gamma ⋅ log | |
| e | |
| 2(y). |
This means that there should on average be about
| \gamma ⋅ log | |
| e | |
| 2(10) |
Mp
More generally, the number of primes p ≤ y such that
| ap-bp | |
| a-b |
| \gamma+m ⋅ log | |
| (e | |
| e(2)) ⋅ log |
a(y).
where m is the largest nonnegative integer such that a and −b are both perfect 2m-th powers. The case of Mersenne primes is one case of (a, b) = (2, 1).