On odd-normal numbers

Abstract

A real number x is considered normal in an integer base b ≥ 2 if its digit expansion in this base is ``equitable'', ensuring that for each k ≥ 1, every ordered sequence of k digits from \0, 1, …, b-1\ occurs in the digit expansion of x with the same limiting frequency. Borel's classical result b09 asserts that Lebesgue-almost every x ∈ R is normal in every base b ≥ 2. This paper serves as a case study of the measure-theoretic properties of Lebesgue-null sets containing numbers that are normal only in certain bases. We consider the set N(O, E) of reals that are normal in odd bases but not in even ones. This set has full Hausdorff dimension p81 but zero Fourier dimension. The latter condition means that N(O, E) cannot support a probability measure whose Fourier transform has power decay at infinity. Our main result is that N(O, E) supports a Rajchman measure μ, whose Fourier transform μ() approaches 0 as || → ∞ by definiton, albeit slower than any negative power of ||. Moreover, the decay rate of μ is essentially optimal, subject to the constraints of its support. The methods draw inspiration from the number-theoretic results of Schmidt s60 and a construction of Lyons l86. As a consequence, N(O, E) emerges as a set of multiplicity, in the sense of Fourier analysis. This addresses a question posed by Kahane and Salem Kahane-Salem-64 in the special case of N(O, E).