Repunit prime

In recreational mathematics, a repunit is a number like 11, 111, or 1111 that contains only the digit 1 — a more specific type of repdigit. The term stands for repeated unit and was coined in 1966 by Albert H. Beiler in his book ''Recreations in the Theory of Numbers''.

A repunit prime is a repunit that is also a prime number. Primes that are repunits in base-2 are Mersenne primes. As of March 2022, the largest known prime number , the largest probable prime ''R''_8177207 and the largest elliptic curve primality prime ''R''₄₉₀₈₁ are all repunits.

Definition

The base-''b'' repunits are defined as (this ''b'' can be either positive or negative)
:$R_n^\equiv 1 + b + b^2 + \cdots + b^ = \qquad\mbox, b, \ge2, n\ge1.$
Thus, the number ''R''_''n''^(''b'') consists of ''n'' copies of the digit 1 in base-''b'' representation. The first two repunits base-''b'' for ''n'' = 1 and ''n'' = 2 are
:$R_1^$

1 \qquad \text \qquad R_2^

b+1\qquad\text\ , b, \ge2.

In particular, the ''decimal (base-''10'') repunits'' that are often referred to as simply ''repunits'' are defined as
:$R_n \equiv R_n^ = = \qquad\mbox n \ge 1.$
Thus, the number ''R''_''n'' = ''R''_''n''⁽¹⁰⁾ consists of ''n'' copies of the digit 1 in base 10 representation. The sequence of repunits base-10 starts with
: 1, 11, 111, 1111, 11111, 111111, ... .

Similarly, the repunits base-2 are defined as
:$R_n^ = = \qquad\mboxn \ge 1.$
Thus, the number ''R''_''n''⁽²⁾ consists of ''n'' copies of the digit 1 in base-2 representation. In fact, the base-2 repunits are the well-known Mersenne numbers ''M''_''n'' = 2^''n'' − 1, they start with
:1, 3, 7, 15, 31, 63, 127, 255, 511, 1023, 2047, 4095, 8191, 16383, 32767, 65535, ... .

Properties

* Any repunit in any base having a composite number of digits is necessarily composite. Only repunits (in any base) having a prime number of digits might be prime. This is a necessary but not sufficient condition. For example,
*: ''R''₃₅^(''b'') = = 11111 × 1000010000100001000010000100001 = 1111111 × 10000001000000100000010000001,
:since 35 = 7 × 5 = 5 × 7. This repunit factorization does not depend on the base-''b'' in which the repunit is expressed.
* If ''p'' is an odd prime, then every prime ''q'' that divides ''R''_''p''^(''b'') must be either 1 plus a multiple of 2''p,'' or a factor of ''b'' − 1. For example, a prime factor of ''R''₂₉ is 62003 = 1 + 2·29·1069. The reason is that the prime ''p'' is the smallest exponent greater than 1 such that ''q'' divides ''b^p'' − 1, because ''p'' is prime. Therefore, unless ''q'' divides ''b'' − 1, ''p'' divides the Carmichael function of ''q'', which is even and equal to ''q'' − 1.
*Any positive multiple of the repunit ''R''_''n''^(''b'') contains at least ''n'' nonzero digits in base-''b''.
* Any number ''x'' is a two-digit repunit in base x − 1.
* The only known numbers that are repunits with at least 3 digits in more than one base simultaneously are 31 (111 in base-5, 11111 in base-2) and 8191 (111 in base-90, 1111111111111 in base-2). The Goormaghtigh conjecture says there are only these two cases.
* Using the pigeon-hole principle it can be easily shown that for relatively prime natural numbers ''n'' and ''b'', there exists a repunit in base-''b'' that is a multiple of ''n''. To see this consider repunits ''R''₁^(''b''),...,''R''_''n''^(''b''). Because there are ''n'' repunits but only ''n''−1 non-zero residues modulo ''n'' there exist two repunits ''R''_''i''^(''b'') and ''R''_''j''^(''b'') with 1 ≤ ''i'' < ''j'' ≤ ''n'' such that ''R''_''i''^(''b'') and ''R''_''j''^(''b'') have the same residue modulo ''n''. It follows that ''R''_''j''^(''b'') − ''R''_''i''^(''b'') has residue 0 modulo ''n'', i.e. is divisible by ''n''. Since ''R''_''j''^(''b'') − ''R''_''i''^(''b'') consists of ''j'' − ''i'' ones followed by ''i'' zeroes, . Now ''n'' divides the left-hand side of this equation, so it also divides the right-hand side, but since ''n'' and ''b'' are relatively prime, ''n'' must divide ''R''_{''j''−''i''}^(''b'').
* The Feit–Thompson conjecture is that ''R''_''q''^(''p'') never divides ''R''_''p''^(''q'') for two distinct primes ''p'' and ''q''.
* Using the Euclidean Algorithm for repunits definition: ''R''₁^(''b'') = 1; ''R''_''n''^(''b'') = ''R''_''n''−1^(''b'') × ''b'' + 1, any consecutive repunits ''R''_''n''−1^(''b'') and ''R''_''n''^(''b'') are relatively prime in any base-''b'' for any ''n''.
* If ''m'' and ''n'' have a common divisor ''d'', ''R''_''m''^(''b'') and ''R''_''n''^(''b'') have the common divisor ''R''_''d''^(''b'') in any base-''b'' for any ''m'' and ''n''. That is, the repunits of a fixed base form a strong divisibility sequence. As a consequence, If ''m'' and ''n'' are relatively prime, ''R''_''m''^(''b'') and ''R''_''n''^(''b'') are relatively prime. The Euclidean Algorithm is based on ''gcd''(''m'', ''n'') = ''gcd''(''m'' − ''n'', ''n'') for ''m'' > ''n''. Similarly, using ''R''_''m''^(''b'') − ''R''_''n''^(''b'') × ''b''^{''m''−''n''} = ''R''_{''m''−''n''}^(''b''), it can be easily shown that ''gcd''(''R''_''m''^(''b''), ''R''_''n''^(''b'')) = ''gcd''(''R''_{''m''−''n''}^(''b''), ''R''_''n''^(''b'')) for ''m'' > ''n''. Therefore, if ''gcd''(''m'', ''n'') = ''d'', then ''gcd''(''R''_''m''^(''b''), ''R''_''n''^(''b'')) = ''R_d''^(''b'').

Factorization of decimal repunits

(Prime factors colored means "new factors", i. e. the prime factor divides ''R''_''n'' but does not divide ''R''_''k'' for all ''k'' < ''n'')

Smallest prime factor of ''R''_''n'' for ''n'' > 1 are
:11, 3, 11, 41, 3, 239, 11, 3, 11, 21649, 3, 53, 11, 3, 11, 2071723, 3, 1111111111111111111, 11, 3, 11, 11111111111111111111111, 3, 41, 11, 3, 11, 3191, 3, 2791, 11, 3, 11, 41, 3, 2028119, 11, 3, 11, 83, 3, 173, 11, 3, 11, 35121409, 3, 239, 11, ...

Repunit primes

The definition of repunits was motivated by recreational mathematicians looking for prime factors of such numbers.

It is easy to show that if ''n'' is divisible by ''a'', then ''R''_''n''^(''b'') is divisible by ''R''_''a''^(''b''):

:$R_n^=\frac\prod_\Phi_d(b),$

where $\Phi_d(x)$ is the $d^\mathrm$ cyclotomic polynomial and ''d'' ranges over the divisors of ''n''. For ''p'' prime,

:$\Phi_p(x)=\sum_^x^i,$

which has the expected form of a repunit when ''x'' is substituted with ''b''.

For example, 9 is divisible by 3, and thus ''R''₉ is divisible by ''R''₃—in fact, 111111111 = 111 · 1001001. The corresponding cyclotomic polynomials $\Phi_3(x)$ and $\Phi_9(x)$ are $x^2+x+1$ and $x^6+x^3+1$, respectively. Thus, for ''R''_''n'' to be prime, ''n'' must necessarily be prime, but it is not sufficient for ''n'' to be prime. For example, ''R''₃ = 111 = 3 · 37 is not prime. Except for this case of ''R''₃, ''p'' can only divide ''R''_''n'' for prime ''n'' if ''p'' = 2''kn'' + 1 for some ''k''.

Decimal repunit primes

''R''_''n'' is prime for ''n'' = 2, 19, 23, 317, 1031, 49081 ... (sequence A004023 in OEIS). ''R''₈₆₄₅₃ is probably prime. On April 3, 2007 Harvey Dubner (who also found ''R''₄₉₀₈₁) announced that ''R''₁₀₉₂₉₇ is a probable prime. On July 15, 2007, Maksym Voznyy announced ''R''₂₇₀₃₄₃ to be probably prime. Serge Batalov and Ryan Propper found ''R''_5794777 and ''R''_8177207 to be probable primes on April 20 and May 8, 2021, respectively. As of their discovery each was the largest known probable prime. On March 22, 2022 probable prime ''R''₄₉₀₈₁ was eventually proven to be a prime.

It has been conjectured that there are infinitely many repunit primes and they seem to occur roughly as often as the prime number theorem would predict: the exponent of the ''N''th repunit prime is generally around a fixed multiple of the exponent of the (''N''−1)th.

The prime repunits are a trivial subset of the permutable primes, i.e., primes that remain prime after any permutation of their digits.

Particular properties are

*The remainder of ''R''_''n'' modulo 3 is equal to the remainder of ''n'' modulo 3. Using 10^''a'' ≡ 1 (mod 3) for any ''a'' ≥ 0,
''n'' ≡ 0 (mod 3) ⇔ ''R''_''n'' ≡ 0 (mod 3) ⇔ ''R''_''n'' ≡ 0 (mod ''R''₃),
''n'' ≡ 1 (mod 3) ⇔ ''R''_''n'' ≡ 1 (mod 3) ⇔ ''R''_''n'' ≡ ''R''₁ ≡ 1 (mod ''R''₃),
''n'' ≡ 2 (mod 3) ⇔ ''R''_''n'' ≡ 2 (mod 3) ⇔ ''R''_''n'' ≡ ''R''₂ ≡ 11 (mod ''R''₃).
Therefore, 3 , ''n'' ⇔ 3 , ''R''_''n'' ⇔ ''R''₃ , ''R''_''n''.
* The remainder of ''R''_''n'' modulo 9 is equal to the remainder of ''n'' modulo 9. Using 10^''a'' ≡ 1 (mod 9) for any ''a'' ≥ 0,
''n'' ≡ ''r'' (mod 9) ⇔ ''R''_''n'' ≡ ''r'' (mod 9) ⇔ ''R''_''n'' ≡ ''R''_''r'' (mod ''R''₉),
for 0 ≤ ''r'' < 9.
Therefore, 9 , ''n'' ⇔ 9 , ''R''_''n'' ⇔ ''R''₉ , ''R''_''n''.

Base 2 repunit primes

Base-2 repunit primes are called Mersenne primes.

Base 3 repunit primes

The first few base-3 repunit primes are
: 13, 1093, 797161, 3754733257489862401973357979128773, 6957596529882152968992225251835887181478451547013 ,
corresponding to $n$ of
: 3, 7, 13, 71, 103, 541, 1091, 1367, 1627, 4177, 9011, 9551, ... .

Base 4 repunit primes

The only base-4 repunit prime is 5 ($11_4$). $4^n-1 = \left(2^n+1\right)\left(2^n-1\right)$, and 3 always divides $2^n + 1$ when ''n'' is odd and $2^n - 1$ when ''n'' is even. For ''n'' greater than 2, both $2^n + 1$ and $2^n - 1$ are greater than 3, so removing the factor of 3 still leaves two factors greater than 1. Therefore, the number cannot be prime.

Base 5 repunit primes

The first few base-5 repunit primes are
: 31, 19531, 12207031, 305175781, 177635683940025046467781066894531, 14693679385278593849609206715278070972733319459651094018859396328480215743184089660644531, 35032461608120426773093239582247903282006548546912894293926707097244777067146515037165954709053039550781, 815663058499815565838786763657068444462645532258620818469829556933715405574685778402862015856733535201783524826169013977050781 ,
corresponding to $n$ of
: 3, 7, 11, 13, 47, 127, 149, 181, 619, 929, 3407, ... .

Base 6 repunit primes

The first few base-6 repunit primes are
: 7, 43, 55987, 7369130657357778596659, 3546245297457217493590449191748546458005595187661976371, 133733063818254349335501779590081460423013416258060407531857720755181857441961908284738707408499507 ,
corresponding to $n$ of
: 2, 3, 7, 29, 71, 127, 271, 509, 1049, 6389, 6883, ... .

Base 7 repunit primes

The first few base-7 repunit primes are
: 2801, 16148168401, 85053461164796801949539541639542805770666392330682673302530819774105141531698707146930307290253537320447270457,
138502212710103408700774381033135503926663324993317631729227790657325163310341833227775945426052637092067324133850503035623601
corresponding to $n$ of
: 5, 13, 131, 149, 1699, ... .

Base 8 repunit primes

The only base-8 repunit prime is 73 ($111_8$). $8^n - 1=\left(4^n+2^n+1\right)\left(2^n - 1\right)$, and 7 divides $4^n + 2^n + 1$ when ''n'' is not divisible by 3 and $2^n - 1$ when ''n'' is a multiple of 3.

Base 9 repunit primes

There are no base-9 repunit primes. $9^n - 1=\left(3^n + 1\right)\left(3^n - 1\right)$, and both $3^n+1$ and $3^n - 1$ are even and greater than 4.

Base 11 repunit primes

The first few base-11 repunit primes are
: 50544702849929377, 6115909044841454629, 1051153199500053598403188407217590190707671147285551702341089650185945215953, 567000232521795739625828281267171344486805385881217575081149660163046217465544573355710592079769932651989153833612198334843467861091902034340949
corresponding to $n$ of
: 17, 19, 73, 139, 907, 1907, 2029, 4801, 5153, 10867, ... .

Base 12 repunit primes

The first few base-12 repunit primes are
: 13, 157, 22621, 29043636306420266077, 43570062353753446053455610056679740005056966111842089407838902783209959981593077811330507328327968191581, 388475052482842970801320278964160171426121951256610654799120070705613530182445862582590623785872890159937874339918941
corresponding to $n$ of
: 2, 3, 5, 19, 97, 109, 317, 353, 701, 9739, ... .

Base 20 repunit primes

The first few base-20 repunit primes are
: 421, 10778947368421, 689852631578947368421
corresponding to $n$ of
: 3, 11, 17, 1487, ... .

Bases ''b'' such that ''R_p''(b) is prime for prime ''p''

Smallest base $b$ such that $R_p(b)$ is prime (where $p$ is the $n$th prime) are

:2, 2, 2, 2, 5, 2, 2, 2, 10, 6, 2, 61, 14, 15, 5, 24, 19, 2, 46, 3, 11, 22, 41, 2, 12, 22, 3, 2, 12, 86, 2, 7, 13, 11, 5, 29, 56, 30, 44, 60, 304, 5, 74, 118, 33, 156, 46, 183, 72, 606, 602, 223, 115, 37, 52, 104, 41, 6, 338, 217, 13, 136, 220, 162, 35, 10, 218, 19, 26, 39, 12, 22, 67, 120, 195, 48, 54, 463, 38, 41, 17, 808, 404, 46, 76, 793, 38, 28, 215, 37, 236, 59, 15, 514, 260, 498, 6, 2, 95, 3, ...

Smallest base $b$ such that $R_p(-b)$ is prime (where $p$ is the $n$th prime) are

:3, 2, 2, 2, 2, 2, 2, 2, 2, 7, 2, 16, 61, 2, 6, 10, 6, 2, 5, 46, 18, 2, 49, 16, 70, 2, 5, 6, 12, 92, 2, 48, 89, 30, 16, 147, 19, 19, 2, 16, 11, 289, 2, 12, 52, 2, 66, 9, 22, 5, 489, 69, 137, 16, 36, 96, 76, 117, 26, 3, 159, 10, 16, 209, 2, 16, 23, 273, 2, 460, 22, 3, 36, 28, 329, 43, 69, 86, 271, 396, 28, 83, 302, 209, 11, 300, 159, 79, 31, 331, 52, 176, 3, 28, 217, 14, 410, 252, 718, 164, ...

List of repunit primes base ''b''

Smallest prime $p>2$ such that $R_p(b)$ is prime are (start with $b=2$, 0 if no such $p$ exists)

:3, 3, 0, 3, 3, 5, 3, 0, 19, 17, 3, 5, 3, 3, 0, 3, 25667, 19, 3, 3, 5, 5, 3, 0, 7, 3, 5, 5, 5, 7, 0, 3, 13, 313, 0, 13, 3, 349, 5, 3, 1319, 5, 5, 19, 7, 127, 19, 0, 3, 4229, 103, 11, 3, 17, 7, 3, 41, 3, 7, 7, 3, 5, 0, 19, 3, 19, 5, 3, 29, 3, 7, 5, 5, 3, 41, 3, 3, 5, 3, 0, 23, 5, 17, 5, 11, 7, 61, 3, 3, 4421, 439, 7, 5, 7, 3343, 17, 13, 3, 0, ...

Smallest prime $p>2$ such that $R_p(-b)$ is prime are (start with $b=2$, 0 if no such $p$ exists, question mark if this term is currently unknown)

:3, 3, 3, 5, 3, 3, 0, 3, 5, 5, 5, 3, 7, 3, 3, 7, 3, 17, 5, 3, 3, 11, 7, 3, 11, 0, 3, 7, 139, 109, 0, 5, 3, 11, 31, 5, 5, 3, 53, 17, 3, 5, 7, 103, 7, 5, 5, 7, 1153, 3, 7, 21943, 7, 3, 37, 53, 3, 17, 3, 7, 11, 3, 0, 19, 7, 3, 757, 11, 3, 5, 3, 7, 13, 5, 3, 37, 3, 3, 5, 3, 293, 19, 7, 167, 7, 7, 709, 13, 3, 3, 37, 89, 71, 43, 37, ?, 19, 7, 3, ...

^* Repunits with negative base and even ''n'' are negative. If their absolute value is prime then they are included above and marked with an asterisk. They are not included in the corresponding OEIS sequences.

For more information, see.

Algebra factorization of generalized repunit numbers

If ''b'' is a perfect power (can be written as ''m''^''n'', with ''m'', ''n'' integers, ''n'' > 1) differs from 1, then there is at most one repunit in base-''b''. If ''n'' is a prime power (can be written as ''p''^''r'', with ''p'' prime, ''r'' integer, ''p'', ''r'' >0), then all repunit in base-''b'' are not prime aside from ''R_p'' and ''R₂''. ''R_p'' can be either prime or composite, the former examples, ''b'' = −216, −128, 4, 8, 16, 27, 36, 100, 128, 256, etc., the latter examples, ''b'' = −243, −125, −64, −32, −27, −8, 9, 25, 32, 49, 81, 121, 125, 144, 169, 196, 216, 225, 243, 289, etc., and ''R₂'' can be prime (when ''p'' differs from 2) only if ''b'' is negative, a power of −2, for example, ''b'' = −8, −32, −128, −8192, etc., in fact, the ''R₂'' can also be composite, for example, ''b'' = −512, −2048, −32768, etc. If ''n'' is not a prime power, then no base-''b'' repunit prime exists, for example, ''b'' = 64, 729 (with ''n'' = 6), ''b'' = 1024 (with ''n'' = 10), and ''b'' = −1 or 0 (with ''n'' any natural number). Another special situation is ''b'' = −4''k''⁴, with ''k'' positive integer, which has the aurifeuillean factorization, for example, ''b'' = −4 (with ''k'' = 1, then ''R₂'' and ''R₃'' are primes), and ''b'' = −64, −324, −1024, −2500, −5184, ... (with ''k'' = 2, 3, 4, 5, 6, ...), then no base-''b'' repunit prime exists. It is also conjectured that when ''b'' is neither a perfect power nor −4''k''⁴ with ''k'' positive integer, then there are infinity many base-''b'' repunit primes.

The generalized repunit conjecture

A conjecture related to the generalized repunit primes: (the conjecture predicts where is the next generalized Mersenne prime, if the conjecture is true, then there are infinitely many repunit primes for all bases $b$)

For any integer $b$, which satisfies the conditions:

# $, b, >1$.
# $b$ is not a perfect power. (since when $b$ is a perfect $r$th power, it can be shown that there is at most one $n$ value such that $\frac$ is prime, and this $n$ value is $r$ itself or a root of $r$)
# $b$ is not in the form $-4k^4$. (if so, then the number has aurifeuillean factorization)

has generalized repunit primes of the form

:$R_p(b)=\frac$

for prime $p$, the prime numbers will be distributed near the best fit line

:$Y=G \cdot \log_\left( \log_\left( R_(n) \right) \right)+C,$

where limit $n\rightarrow\infty$, $G=\frac=0.561459483566...$

and there are about

:$\left( \log_e(N)+m \cdot \log_e(2) \cdot \log_e \big( \log_e(N) \big) +\frac-\delta \right) \cdot \frac$

base-''b'' repunit primes less than ''N''.

*$e$ is the base of natural logarithm.
*$\gamma$ is Euler–Mascheroni constant.
*$\log_$ is the logarithm in base $, b,$
*$R_(n)$ is the $n$th generalized repunit prime in base''b'' (with prime ''p'')
*$C$ is a data fit constant which varies with $b$.
*$\delta=1$ if $b>0$, $\delta=1.6$ if $b<0$.
*$m$ is the largest natural number such that $-b$ is a $2^$th power.

We also have the following 3 properties:

# The number of prime numbers of the form $\frac$ (with prime $p$) less than or equal to $n$ is about $e^\gamma \cdot \log_\big(\log_(n)\big)$.
# The expected number of prime numbers of the form $\frac$ with prime $p$ between $n$ and $, b, \cdot n$ is about $e^\gamma$.
# The probability that number of the form $\frac$ is prime (for prime $p$) is about $\frac$.

History

Although they were not then known by that name, repunits in base-10 were studied by many mathematicians during the nineteenth century in an effort to work out and predict the cyclic patterns of repeating decimals.

It was found very early on that for any prime ''p'' greater than 5, the period of the decimal expansion of 1/''p'' is equal to the length of the smallest repunit number that is divisible by ''p''. Tables of the period of reciprocal of primes up to 60,000 had been published by 1860 and permitted the factorization by such mathematicians as Reuschle of all repunits up to ''R₁₆'' and many larger ones. By 1880, even ''R₁₇'' to ''R₃₆'' had been factored and it is curious that, though Édouard Lucas showed no prime below three million had period nineteen, there was no attempt to test any repunit for primality until early in the twentieth century. The American mathematician Oscar Hoppe proved ''R₁₉'' to be prime in 1916 and Lehmer and Kraitchik independently found ''R₂₃'' to be prime in 1929.

Further advances in the study of repunits did not occur until the 1960s, when computers allowed many new factors of repunits to be found and the gaps in earlier tables of prime periods corrected. ''R₃₁₇'' was found to be a probable prime circa 1966 and was proved prime eleven years later, when ''R₁₀₃₁'' was shown to be the only further possible prime repunit with fewer than ten thousand digits. It was proven prime in 1986, but searches for further prime repunits in the following decade consistently failed. However, there was a major side-development in the field of generalized repunits, which produced a large number of new primes and probable primes.

Since 1999, four further probably prime repunits have been found, but it is unlikely that any of them will be proven prime in the foreseeable future because of their huge size.

The Cunningham project endeavours to document the integer factorizations of (among other numbers) the repunits to base 2, 3, 5, 6, 7, 10, 11, and 12.

Demlo numbers

D. R. Kaprekar has defined Demlo numbers as concatenation of a left, middle and right part, where the left and right part must be of the same length (up to a possible leading zero to the left) and must add up to a repdigit number, and the middle part may contain any additional number of this repeated digit.
They are named after Demlo railway station (now called Dombivili) 30 miles from Bombay on the then G.I.P. Railway, where Kaprekar started investigating them.
He calls ''Wonderful Demlo numbers'' those of the form 1, 121, 12321, 1234321, ..., 12345678987654321. The fact that these are the squares of the repunits has led some authors to call Demlo numbers the infinite sequence of these, 1, 121, 12321, ..., 12345678987654321, 1234567900987654321, 123456790120987654321, ..., , although one can check these are not Demlo numbers for ''p'' = 10, 19, 28, ...

See also

* All one polynomial — Another generalization
* Goormaghtigh conjecture
* Repeating decimal
* Repdigit
* Wagstaff prime — can be thought of as repunit primes with negative base $b = -2$

Footnotes

Notes

References

References

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External links

*
The main tables
of th
Cunningham project

Repunit
at The Prime Pages by Chris Caldwell.
Repunits and their prime factors
a
World!Of Numbers


of at least 1000 decimal digits by Andy Steward

Giovanni Di Maria's repunit primes page.
Smallest odd prime p such that (b^p-1)/(b-1) and (b^p+1)/(b+1) is prime for bases 2<=b<=1024Factorization of repunit numbers

{{Prime number classes

Integers
Base-dependent integer sequences