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number theory Number theory (or arithmetic or higher arithmetic in older usage) is a branch of pure mathematics devoted primarily to the study of the integers and arithmetic function, integer-valued functions. German mathematician Carl Friedrich Gauss (1777â ...
, Mills' constant is defined as the smallest positive
real number In mathematics, a real number is a number that can be used to measure a ''continuous'' one-dimensional quantity such as a distance, duration or temperature. Here, ''continuous'' means that values can have arbitrarily small variations. Every real ...
''A'' such that the
floor function In mathematics and computer science, the floor function is the function that takes as input a real number , and gives as output the greatest integer less than or equal to , denoted or . Similarly, the ceiling function maps to the least int ...
of the
double exponential function A double exponential function is a constant raised to the power of an exponential function. The general formula is f(x) = a^=a^ (where ''a''>1 and ''b''>1), which grows much more quickly than an exponential function. For example, if ''a'' = ''b ...
: \lfloor A^ \rfloor is a
prime number A prime number (or a prime) is a natural number greater than 1 that is not a product of two smaller natural numbers. A natural number greater than 1 that is not prime is called a composite number. For example, 5 is prime because the only ways ...
for all
natural number In mathematics, the natural numbers are those numbers used for counting (as in "there are ''six'' coins on the table") and ordering (as in "this is the ''third'' largest city in the country"). Numbers used for counting are called ''Cardinal n ...
s ''n''. This constant is named after William Harold Mills who proved in 1947 the existence of ''A'' based on results of
Guido Hoheisel Guido Karl Heinrich Hoheisel (14 July 1894 – 11 October 1968) was a German mathematician and professor of mathematics at the University of Cologne. Academic life He did his PhD in 1920 from the University of Berlin under the supervision of Er ...
and
Albert Ingham Albert Edward Ingham (3 April 1900 – 6 September 1967) was an English mathematician. Early life and education Ingham was born in Northampton. He went to Stafford Grammar School and began his studies at Trinity College, Cambridge in January 1 ...
on the
prime gap A prime gap is the difference between two successive prime numbers. The ''n''-th prime gap, denoted ''g'n'' or ''g''(''p'n'') is the difference between the (''n'' + 1)-th and the ''n''-th prime numbers, i.e. :g_n = p_ - p_n.\ W ...
s. Its value is unknown, but if the
Riemann hypothesis In mathematics, the Riemann hypothesis is the conjecture that the Riemann zeta function has its zeros only at the negative even integers and complex numbers with real part . Many consider it to be the most important unsolved problem in ...
is true, it is approximately 1.3063778838630806904686144926... .


Mills primes

The primes generated by Mills' constant are known as Mills primes; if the Riemann hypothesis is true, the sequence begins :2, 11, 1361, 2521008887, 16022236204009818131831320183, 4113101149215104800030529537915953170486139623539759933135949994882770404074832568499, \ldots . If ''ai'' denotes the ''i'' th prime in this sequence, then ''ai'' can be calculated as the smallest prime number larger than a_^3. In order to ensure that rounding A^, for ''n'' = 1, 2, 3, …, produces this sequence of primes, it must be the case that a_i < (a_+1)^3. The Hoheisel–Ingham results guarantee that there exists a prime between any two sufficiently large
cube number In arithmetic and algebra, the cube of a number is its third power, that is, the result of multiplying three instances of together. The cube of a number or any other mathematical expression is denoted by a superscript 3, for example or . T ...
s, which is sufficient to prove this inequality if we start from a sufficiently large first prime a_1. The Riemann hypothesis implies that there exists a prime between any two consecutive cubes, allowing the ''sufficiently large'' condition to be removed, and allowing the sequence of Mills primes to begin at ''a''1 = 2. For all a > e^, there is at least one prime between a^3 and (a+1)^3. This upper bound is much too large to be practical, as it is infeasible to check every number below that figure. However, the value of Mills' constant can be verified by calculating the first prime in the sequence that is greater than that figure. As of April 2017, the 11th number in the sequence is the largest one that has been ''proved'' prime. It is :\displaystyle (((((((((2^3+3)^3+30)^3+6)^3+80)^3+12)^3+450)^3+894)^3+3636)^3+70756)^3+97220 and has 20562 digits. , the largest known Mills ''probable'' prime (under the Riemann hypothesis) is :\displaystyle ((((((((((((2^3+3)^3+30)^3+6)^3+80)^3+12)^3+450)^3+894)^3+3636)^3+70756)^3+97220)^3+66768)^3+300840)^3+1623568 , which is 555,154 digits long.


Numerical calculation

By calculating the sequence of Mills primes, one can approximate Mills' constant as :A\approx a(n)^. Caldwell and Cheng used this method to compute 6850 base 10 digits of Mills' constant under the assumption that the
Riemann hypothesis In mathematics, the Riemann hypothesis is the conjecture that the Riemann zeta function has its zeros only at the negative even integers and complex numbers with real part . Many consider it to be the most important unsolved problem in ...
is true. There is no closed-form formula known for Mills' constant, and it is not even known whether this number is
rational Rationality is the quality of being guided by or based on reasons. In this regard, a person acts rationally if they have a good reason for what they do or a belief is rational if it is based on strong evidence. This quality can apply to an abili ...
.


Fractional representations

Below are fractions which approximate Mills' constant, listed in order of increasing accuracy (with continued-fraction convergents in bold) : 1/1, 3/2, 4/3, 9/7, 13/10, 17/13, 47/36, 64/49, 81/62, 145/111, 226/173, 307/235, 840/643, 1147/878, 3134/2399, 4281/3277, 5428/4155, 6575/5033, 12003/9188, 221482/169539, 233485/178727, 245488/187915, 257491/197103, 269494/206291, 281497/215479, 293500/224667, 305503/233855, 317506/243043, 329509/252231, 341512/261419, 353515/270607, 365518/279795, 377521/288983, 389524/298171, 401527/307359, 413530/316547, 425533/325735, 4692866/3592273, 5118399/3918008, 5543932/4243743, 5969465/4569478, 6394998/4895213, 6820531/5220948, 7246064/5546683,7671597/5872418, 8097130/6198153, 8522663/6523888, 8948196/6849623, 9373729/7175358, 27695654/21200339, 37069383/28375697, 46443112/35551055, 148703065/113828523, 195146177/149379578, 241589289/184930633, 436735466/334310211, 1115060221/853551055, 1551795687/1187861266, 1988531153/1522171477, 3540326840/2710032743, 33414737247/25578155953, ...


Generalisations

There is nothing special about the middle exponent value of 3. It is possible to produce similar prime-generating functions for different middle exponent values. In fact, for any real number above 2.106..., it is possible to find a different constant ''A'' that will work with this middle exponent to always produce primes. Moreover, if
Legendre's conjecture Legendre's conjecture, proposed by Adrien-Marie Legendre, states that there is a prime number between n^2 and (n+1)^2 for every positive integer n. The conjecture is one of Landau's problems (1912) on prime numbers; , the conjecture has neither be ...
is true, the middle exponent can be replaced with value 2 . Matomäki showed unconditionally (without assuming Legendre's conjecture) the existence of a (possibly large) constant ''A'' such that \lfloor A^ \rfloor is prime for all ''n''. Additionally, Tóth proved that the floor function in the formula could be replaced with the
ceiling function In mathematics and computer science, the floor function is the function that takes as input a real number , and gives as output the greatest integer less than or equal to , denoted or . Similarly, the ceiling function maps to the least inte ...
, so that there exists a constant B such that :\lceil B^ \rceil is also prime-representing for r>2.106\ldots. In the case r=3, the value of the constant B begins with 1.24055470525201424067... The first few primes generated are: :2, 7, 337, 38272739, 56062005704198360319209, 176199995814327287356671209104585864397055039072110696028654438846269, \ldots ''Without'' assuming the Riemann hypothesis, Elsholtz proved that \lfloor A^ \rfloor is prime for all positive integers , where A \approx 1.00536773279814724017, and that \lfloor B^ \rfloor is prime for all positive integers , where B \approx 3.8249998073439146171615551375.


See also

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Formula for primes In number theory, a formula for primes is a formula generating the prime numbers, exactly and without exception. No such formula which is efficiently computable is known. A number of constraints are known, showing what such a "formula" can and can ...


References


Further reading

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External links

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Who remembers the Mills number?
E. Kowalski.
Awesome Prime Number Constant
Numberphile. {{Prime number classes Mathematical constants Prime numbers