Anomalous Partial Quotients in the Continued Fraction of ζ(3)-SN

Abstract

Let SN = Σj=1N j-3 and RN = ζ(3) - SN. The simple continued fraction of RN has partial quotients of generic size O(N). We prove that at the sequence of indices Nk = (Q2k+1-1)/2, where Q2k+1 are companion Pell numbers, the continued fraction begins \[ RNk = [0;\; Mk-1,\; 1,\; 6Mk3+12Mk-2,\; 1,\; …\,], \] with Mk = P2k+1 (Pell numbers), and the third partial quotient grows cubically while generic ones are linear. We determine all partial quotients through the fifth: align* 0 &= Mk - 1, & 2 &= 6Mk3 + 12Mk - 2, & 4 &= 10Mk - 261261, 1 &= 1, & 3 &= 1, & 5 &= 261rk + εk, align* where rk = (10Mk) 261 satisfies the recurrence rk+1 6rk - rk-1 261, and εk = -1 at the k with rk 261 (the two residue classes k 57, 62 60), and εk = 0 otherwise. All six formulas follow from the Euler--Maclaurin expansion of 1/RNk, carried to sufficient precision, combined with the Pell identity Q2k+12 - 2Mk2 = -1. The delicate first step, 0 = Mk - 1, is proved by rationalizing the irrational factor 2 in the Euler--Maclaurin expansion; we complement this proof with a heuristic derivation via Gosper's bihomographic continued-fraction algorithm that exposes the underlying mechanism. All claimed results have been formalized in LEAN with the aid of Aristotle.

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