The prime-counting Copeland-Erdos constant

Abstract

Let (a(n) : n ∈ N) denote a sequence of nonnegative integers. Let 0.a(1)a(2)... denote the real number obtained by concatenating the digit expansions, in a fixed base, of consecutive entries of (a(n) : n ∈ N). Research on digit expansions of this form has mainly to do with the normality of 0.a(1)a(2)... for a given base. Famously, the Copeland-Erdos constant 0.2357111317..., for the case whereby a(n) equals the nth prime number pn, is normal in base 10. However, it seems that the ``inverse'' construction given by concatenating the decimal digits of (π(n) : n ∈ N), where π denotes the prime-counting function, has not previously been considered. Exploring the distribution of sequences of digits in this new constant 0.0122...9101011... would be comparatively difficult, since the number of times a fixed m ∈ N appears in (π(n) : n ∈ N) is equal to the prime gap gm = pm+1 - pm, with the behaviour of prime gaps notoriously elusive. Using a combinatorial method due to Sz\"usz and Volkmann, we prove that Cram\'er's conjecture on prime gaps implies the normality of 0.a(1)a(2)... in a given base g ≥ 2, for a(n) = π(n).