Conditional Bounds for Prime Gaps with Applications
Abstract
We posit that dn2 < 2pn+1 holds for all n≥ 1, where pn represents the nth prime and dn stands for the nth prime gap i.e. dn := pn+1 - pn. Then, the presence of a prime between successive perfect squares, as well as the validity of n := pn+1 - pn < 1 are derived. Next, π(x) being the number of primes p up to x, we deduce π(n2-n) < π(n2) < π(n2+n) (n≥ 2). In addition, a proof of π((n+1)k) - π(nk) ≥ π(2k) \ (k≥ 2, n≥ 1) is worked out. The vanishing nature of n as n goes to infinity is set, and used afterwards to achieve both n→∞dn/pn = 0 and the twin prime conjecture. Also, question about the estimate pn < 2jn2 \ (n≥ 6), where jn counts the twin prime pairs up to pn, is raised. Finally, we put forward the conjecture that any rational number r (0≤ r ≤ 1) represents an accumulation point of the sequence (\pn\)n≥ 1, where \x\ acts for the fractional part of x.
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