Formally, Sylvester's sequence can be defined by the formula

${\displaystyle s_{n}=1+\prod _{i=0}^{n-1}s_{i}.}$ 

The product of the empty set is 1, so s₀ = 2.

Alternatively, one may define the sequence by the recurrence

${\displaystyle \displaystyle s_{i}=s_{i-1}(s_{i-1}-1)+1,}$  with s₀ = 2.

It is straightforward to show by induction that this is equivalent to the other definition.

The Sylvester numbers grow doubly exponentially as a function of n. Specifically, it can be shown that

${\displaystyle s_{n}=\left\lfloor E^{2^{n+1}}+{\frac {1}{2}}\right\rfloor ,\!}$ 

for a number E that is approximately 1.26408473530530...^[1] (sequence A076393 in the OEIS). This formula has the effect of the following algorithm:

s₀ is the nearest integer to E²; s₁ is the nearest integer to E⁴; s₂ is the nearest integer to E⁸; for s_n, take E², square it n more times, and take the nearest integer.

This would only be a practical algorithm if we had a better way of calculating E to the requisite number of places than calculating s_n and taking its repeated square root.

The double-exponential growth of the Sylvester sequence is unsurprising if one compares it to the sequence of Fermat numbers F_n; the Fermat numbers are usually defined by a doubly exponential formula, ${\displaystyle 2^{2^{n}}\!+1}$ , but they can also be defined by a product formula very similar to that defining Sylvester's sequence:

${\displaystyle F_{n}=2+\prod _{i=0}^{n-1}F_{i}.}$ 

The unit fractions formed by the reciprocals of the values in Sylvester's sequence generate an infinite series:

${\displaystyle \sum _{i=0}^{\infty }{\frac {1}{s_{i}}}={\frac {1}{2}}+{\frac {1}{3}}+{\frac {1}{7}}+{\frac {1}{43}}+{\frac {1}{1807}}+\cdots .}$ 

The partial sums of this series have a simple form,

${\displaystyle \sum _{i=0}^{j-1}{\frac {1}{s_{i}}}=1-{\frac {1}{s_{j}-1}}={\frac {s_{j}-2}{s_{j}-1}}.}$ 

This may be proved by induction, or more directly by noting that the recursion implies that

${\displaystyle {\frac {1}{s_{i}-1}}-{\frac {1}{s_{i+1}-1}}={\frac {1}{s_{i}}},}$ 

so the sum telescopes

${\displaystyle \sum _{i=0}^{j-1}{\frac {1}{s_{i}}}=\sum _{i=0}^{j-1}\left({\frac {1}{s_{i}-1}}-{\frac {1}{s_{i+1}-1}}\right)={\frac {1}{s_{0}-1}}-{\frac {1}{s_{j}-1}}=1-{\frac {1}{s_{j}-1}}.}$ 

Since this sequence of partial sums (s_j − 2)/(s_j − 1) converges to one, the overall series forms an infinite Egyptian fraction representation of the number one:

${\displaystyle 1={\frac {1}{2}}+{\frac {1}{3}}+{\frac {1}{7}}+{\frac {1}{43}}+{\frac {1}{1807}}+\cdots .}$ 

One can find finite Egyptian fraction representations of one, of any length, by truncating this series and subtracting one from the last denominator:

${\displaystyle 1={\tfrac {1}{2}}+{\tfrac {1}{3}}+{\tfrac {1}{6}},\quad 1={\tfrac {1}{2}}+{\tfrac {1}{3}}+{\tfrac {1}{7}}+{\tfrac {1}{42}},\quad 1={\tfrac {1}{2}}+{\tfrac {1}{3}}+{\tfrac {1}{7}}+{\tfrac {1}{43}}+{\tfrac {1}{1806}},\quad \dots .}$ 

The sum of the first k terms of the infinite series provides the closest possible underestimate of 1 by any k-term Egyptian fraction.^[2] For example, the first four terms add to 1805/1806, and therefore any Egyptian fraction for a number in the open interval (1805/1806, 1) requires at least five terms.

It is possible to interpret the Sylvester sequence as the result of a greedy algorithm for Egyptian fractions, that at each step chooses the smallest possible denominator that makes the partial sum of the series be less than one. Alternatively, the terms of the sequence after the first can be viewed as the denominators of the odd greedy expansion of 1/2.

As Sylvester himself observed, Sylvester's sequence seems to be unique in having such quickly growing values, while simultaneously having a series of reciprocals that converges to a rational number. This sequence provides an example showing that double-exponential growth is not enough to cause an integer sequence to be an irrationality sequence.^[3]

To make this more precise, it follows from results of Badea (1993) that, if a sequence of integers ${\displaystyle a_{n}}$  grows quickly enough that

${\displaystyle a_{n}\geq a_{n-1}^{2}-a_{n-1}+1,}$ 

and if the series

${\displaystyle A=\sum {\frac {1}{a_{i}}}}$ 

converges to a rational number A, then, for all n after some point, this sequence must be defined by the same recurrence

${\displaystyle a_{n}=a_{n-1}^{2}-a_{n-1}+1}$ 

that can be used to define Sylvester's sequence.

Erdős & Graham (1980) conjectured that, in results of this type, the inequality bounding the growth of the sequence could be replaced by a weaker condition,

${\displaystyle \lim _{n\rightarrow \infty }{\frac {a_{n}}{a_{n-1}^{2}}}=1.}$ 

Badea (1995) surveys progress related to this conjecture; see also Brown (1979).

If i < j, it follows from the definition that s_j ≡ 1 (mod s_i ). Therefore, every two numbers in Sylvester's sequence are relatively prime. The sequence can be used to prove that there are infinitely many prime numbers, as any prime can divide at most one number in the sequence. More strongly, no prime factor of a number in the sequence can be congruent to 5 modulo 6, and the sequence can be used to prove that there are infinitely many primes congruent to 7 modulo 12.^[4]

Much remains unknown about the factorization of the numbers in the Sylvester's sequence. For instance, it is not known if all numbers in the sequence are squarefree, although all the known terms are.

As Vardi (1991) describes, it is easy to determine which Sylvester number (if any) a given prime p divides: simply compute the recurrence defining the numbers modulo p until finding either a number that is congruent to zero (mod p) or finding a repeated modulus. Using this technique he found that 1166 out of the first three million primes are divisors of Sylvester numbers,^[5] and that none of these primes has a square that divides a Sylvester number. The set of primes which can occur as factors of Sylvester numbers is of density zero in the set of all primes:^[6] indeed, the number of such primes less than x is ${\displaystyle O(\pi (x)/\log \log \log x)}$ .^[7]

The following table shows known factorizations of these numbers (except the first four, which are all prime):^[8]

As is customary, Pn and Cn denote prime numbers and unfactored composite numbers n digits long.

Boyer, Galicki & Kollár (2005) use the properties of Sylvester's sequence to define large numbers of Sasakian Einstein manifolds having the differential topology of odd-dimensional spheres or exotic spheres. They show that the number of distinct Sasakian Einstein metrics on a topological sphere of dimension 2n  − 1 is at least proportional to s_n and hence has double exponential growth with n.

As Galambos & Woeginger (1995) describe, Brown (1979) and Liang (1980) used values derived from Sylvester's sequence to construct lower bound examples for online bin packing algorithms. Seiden & Woeginger (2005) similarly use the sequence to lower bound the performance of a two-dimensional cutting stock algorithm.^[9]

Znám's problem concerns sets of numbers such that each number in the set divides but is not equal to the product of all the other numbers, plus one. Without the inequality requirement, the values in Sylvester's sequence would solve the problem; with that requirement, it has other solutions derived from recurrences similar to the one defining Sylvester's sequence. Solutions to Znám's problem have applications to the classification of surface singularities (Brenton and Hill 1988) and to the theory of nondeterministic finite automata.^[10]

D. R. Curtiss (1922) describes an application of the closest approximations to one by k-term sums of unit fractions, in lower-bounding the number of divisors of any perfect number, and Miller (1919) uses the same property to upper bound the size of certain groups.

• Cahen's constant
• Primary pseudoperfect number
• Leonardo number

• , from K. S. Brown's MathPages.
• Weisstein, Eric W. "Sylvester's Sequence". MathWorld.