Asymptotic error terms in Bonse-type inequalities
Abstract
Let pn denote the n-th prime. In 2000, Panaitopol established the inequality p1 ·s pn > pn+1n - π(n) for all n ≥ 2, where π(x) is the prime counting function. In 2021, Yang and Liao refined this by introducing the exponent k(n,x) = n - π(n) + π(n)π( n) - x · π(π(n)), proving the inequality holds for x = 2 and n ≥ 8. In 2022, Marques and Trojovsk\'y extended this to x = 1.4 for n ≥ 21 and conjectured its validity for x = 0.1 when n ≥ 24,154,953. This paper confirms the conjecture by analyzing the error term En(x) = (p1 ·s pn) - k(n,x) pn+1. Also, we derive the asymptotic expansion to En(x) demonstrating that it is positive for all sufficiently large n when x > -2. For each x > -2, we identify a minimal integer (x) such that En(x) > 0 for all n ≥ (x), precisely determining (0.1) = 24,154,953. Additionally, we establish effective upper bounds for (x) both unconditionally and under the Riemann Hypothesis, with the conditional bounds showing a significant improvement. Our analysis fully resolves the conjecture and characterizes (x) as a non-increasing, piecewise constant function, exhibiting discontinuities at a discrete set of threshold points. These results advance the understanding of Bonse-type inequalities and their asymptotic behavior.
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