Euclid-Mullin Sequence and Primes
Erhan Tezcan
Posted on December 1, 2022
In this post, I will talk about a cute-little sequence called Euclid-Mullin Sequence. This sequence comes from a thousand year-old proof on infinitude of primes! Let us begin.
Prime Numbers
Well, what is a prime number to begin with? They are defined as numbers n
such that only n
and 1
can divide them with no remainder. They are quite famous :)
For example, 7
can only be divided by 7
and 1
, nothing else. 1
is not considered to be a prime because it makes things a lot more convenient, but there are those who consider it a prime sometimes. To really jump into the world of primes, see this video by Richard Borcherds, a field medalist!
Infinitely Many Primes
It was long wondered whether there were infinitely many primes. One of the oldest proofs in the book (literally) is Euclid's proof that shows indeed there are infinitely many primes.
- Assume that the set of primes
P
is finite:P = {p_1, p_2, ..., p_k}
. - Calculate a new integer
n = p_1 * p_2 * ... * p_k + 1
. - We can then argue that there exists a smallest factor
q
such that1 < q <= n
. Ifq
were to divide any of the primes inP
, it would have to divide1
too. Since this is not possible,q
must be prime.
Euclid-Mullin Sequence
If we start with a finite set P = {2}
, and iteratively find the smallest factor of the number that is the product of our primes plus one, we get 3, 7, 43, 13, 53, 5, 6221671, 38709183810571, 139, ...
. This is called the Euclid-Mullin Sequence (see OEIS A000945). A very intriguing question we might ask here: can we get every prime via this method?
This happens to be extremely difficult to prove, and no one knows the answer. However, a probabilistic argument states that indeed we are almost certainly getting every prime within this sequence:
- Take a prime
q
. What is the probability that our generatedn
is divisible byq
? - It is
1/q
. To understand why, pickq=2
: you are essentially asking what is the probability thatn
is even. More precisely, in everyq
integers, one of them will be divisible byq
. - The probability that
q
does not dividen
is therefore1-1/q
. - Since we are doing this iteratively, we can ask: what is the probability that
q
does not divide any of the numbers seen until stept
? That would be(1 - 1/q)^t
.
As you take a larger t
, this approaches 0; meaning that eventually there should be a number that is divisible by q
. This is not a proof though, it is just an argument! We have no idea how to prove this for all primes.
If you would like to compute this sequence yourself, here is my Python implementation:
def euclid(cnt: int) -> List[int]:
# product of elements in a list
def prod(list: List[int]) -> int:
ans = list[0]
for i in range(1,len(list)):
ans *= list[i]
return ans
def find_smallest_prime_factor(n: int) -> int:
# start from 3; we dont care about 2 here,
# because n is always odd
i = 3
# increment by 2 every step until you reach sqrt(n)
while i * i <= n:
# if i divides n, return that as the smallest prime factor
if (n % i == 0):
return i
i += 2
# otherwise, n itself is a prime
return n
# initial prime set is just [2]
primes: List[int] = [2]
while (len(primes) < cnt):
# generate the new number. note that this number is always odd
n: int = prod(primes) + 1
# find the smallest prime factor of this number
q: int = find_smallest_prime_factor(n)
# add it to the list of primes
primes.append(q)
return primes
print("Primes:",euclid(10))
Posted on December 1, 2022
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