On powers of the diophantine function :x x(x+1)

Abstract

We treat the functions k: N→ N where :x x := x(x+1). The set \k x+1: \x,k\⊂eq N\ is pairwise coprime; so, the set P of primes is infinite. Our Theorem 4 resorts to the mother sequence, M, that is obtained by factoring the infinite sequence 2,3,4,5,… into prime powers. For each x1 we define the gross x-sequence, γ(x) := x+1; x+1; 2x+1; 3x+1;…, and also the star sequence, x, obtained by factoring the terms of γ(x) into prime powers. It turns out that γ(1) is Sylvester's sequence, A00058 in the Online Encyclopedia of Integer Sequences, OEIS, and that γ(2) is the sequence A082732 in the OEIS. Theorem 3. For every integer x1 there is a prime p(x) that divides no member of \kx+1: k0\. Theorem 4. For each sequence η of powers of primes there are infinitely many subsequences c of M such that numerically η=cj but where the term-set family in M of those cj is formally. pairwise disjoint. Theorem 6. 1/x = Σk=0n-1 1/(kx+1) + 1/(nx) = Σk=0∞ 1/(kx+1) for all \x,n\⊂eq N. Theorem 7. For every x∈ N, when x := xjj=0∞ then Σj=0∞ 1/xj = ∞.

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