Transcendence of the Gaussian Liouville number and relatives

Abstract

The Liouville number, denoted l, is defined by l:=0.100101011101101111100..., where the nth bit is given by 1/2(1+(n)); here is the Liouville function for the parity of prime divisors of n. Presumably the Liouville number is transcendental, though at present, a proof is unattainable. Similarly, define the Gaussian Liouville number by γ:=0.110110011100100111011... where the nth bit reflects the parity of the number of rational Gaussian primes dividing n, 1 for even and 0 for odd. In this paper, we prove that the Gaussian Liouville number and its relatives are transcendental. One such relative is the number Σk=0∞23k23k2+23k+1=0.101100101101100100101..., where the nth bit is determined by the parity of the number of prime divisors that are equivalent to 2 modulo 3. We use methods similar to that of Dekking's proof of the transcendence of the Thue--Morse number Dek1 as well as a theorem of Mahler's Mahl1. (For completeness we provide proofs of all needed results.) This method involves proving the transcendence of formal power series arising as generating functions of completely multiplicative functions.