Novel Aspects Of The Global Regularity Of Primes

Abstract

For any m = 3 ( 2n + 1 ) with \ n ∈ N* , the prime counting function π(m) = 4 + A4(m) + 2 A6(m) where A6(m) and A4(m) are the sets of Twin Primes and "Isolated" Primes, below m, respectively. T(m) = 1 + A2(m) + A4(m) + A6(m) is the number of consecutive odd composite numbers (COCONs) below m. A2(m) is the set of COCONs, below m and distant by 2. With m odd, π(m), T(m) and A2(m) = m - 92 - 3 A6(m) - 2 A4(m) lead to 4 A6(m) + 7 = m - 2 ( T(m) + A4(m) ). \ Hence \ 0 < 1 - 2 m ( T(m) + A4(m) ) < 1. Thus the non-empty unique set S 1 - 2 l ( T(l) + A4(l) ) \ such that \ l = 3 ( 2k + 1 ) with \ k ∈ N* ⊂ R is bounded. Therefore Inf ( S ) exists, is unique and finite. By definition, Inf(S) > 0. Q dense in R also guarantees the latter. S and Inf(S) are independent of m. We then introduce α = Inf ( S ): α is independent of m. We then have 0 < α ≤ 1 - 2 m ( T(m) + A4(m) ) for any m as above. Therefore, 4 A6(m) + 7 ≥ α m, with α > 0 and independent of m. Hence m + ∞ 2 A6(m) = + ∞. Similarly, m + ∞ A4(m) = + ∞ .