![Sample our Mathematics & Statistics journals, sign in here to start your FREE access for 14 days]({"type":"image" , "src" : "/sda/5943/TOC-Subject-Sample-2021-Mathematics-Statistics.jpg"})
Abstract
We investigate the so-called persistence problem of Sloane, exploiting connections with the dynamics of circle maps and the ergodic theory of actions. We also formulate a conjecture concerning the asymptotic distribution of digits in long products of finitely many primes whose truth would, in particular, solve the persistence problem. The heuristics that we propose to complement our numerical studies can be considered in terms of a simple model in statistical mechanics.
Notes
1What we call persistence in this paper is sometimes referred to as multiplicative persistence elsewhere, to distinguish it from the similarly defined concept of additive persistence, introduced in [CitationHinden 74]. Since we will consider only multiplicative persistence, we will have no use for the modifier.
2It is not necessary to use the highly nontrivial result about the full Catalan’s conjecture (concerning the Diophantine equation ax − by = 1; see [CitationMihăilescu 04]). The special case needed here (with bases 2 and 3, which are prime) can be proved by elementary means; see [CitationLeVeque 77, p. 85].
3There are some analogies between Sloane’s question, at least for base 3, and the Collatz conjecture as discussed in [CitationTao 11]. In both cases, one represents the problem by a question about a map on a compact abelian group (here the circle, while one uses the dyadics for the Collatz conjecture). Also, in both cases, one can formulate a main aspect of the problem in terms of powers of 2 in base 3, here by expressing that 2n has at least one zero in its base-3 expansion for all n > 15, and as explained in [CitationTao 11] for the Collatz case.
4Warning: The word “locally” is used here with a different meaning from that used in the study of, e.g., cellular automata; in that other context, the carryover is indeed a very nonlocal effect.
5This conjecture is indeed more general than its elementary counterpart given earlier: the latter corresponds to the cases in which the initial sequence of carryovers in the MA is identically zero.
6It is an old unresolved question whether the sequence of repunits 1, 11, 111, 1111, 11111, … written in the decimal system, say, contains infinitely many primes.
7Here, ‖ · ‖ is the max-norm: if , then
.
8Note that the total number of k-blocks is 3k.