Liouville function


The Liouville Lambda function, denoted by λ and named after Joseph Liouville, is an important arithmetic function.
Its value is +1 if n is the product of an even number of prime numbers, and -1 if it is the product of an odd number of primes.
Explicitly, the fundamental theorem of arithmetic states that any positive integer n can be represented uniquely as a product of powers of primes: where p1 < p2 <... < pk are primes and the aj are positive integers. The prime omega functions count the number of primes, with or without multiplicity:
λ is defined by the formula
λ is completely multiplicative since Ω is completely additive, i.e.: Ω = Ω + Ω. Since 1 has no prime factors, Ω = 0 so λ = 1.
It is related to the Möbius function μ. Write n as n = a2b where b is squarefree, i.e., ω = Ω. Then
The sum of the Liouville function over the divisors of n is the characteristic function of the squares:
Möbius inversion of this formula yields
The Dirichlet inverse of Liouville function is the absolute value of the Möbius function, the characteristic function of the squarefree integers. We also have that.

Series

The Dirichlet series for the Liouville function is related to the Riemann zeta function by
The Lambert series for the Liouville function is
where is the Jacobi theta function.

Conjectures on weighted summatory functions


of the oscillations.
fails; the blue curve shows the oscillatory contribution of the first Riemann zero.

The Pólya conjecture is a conjecture made by George Pólya in 1919. Defining
the conjecture states that for n > 1. This turned out to be false. The smallest counter-example is n = 906150257, found by Minoru Tanaka in 1980. It has since been shown that L > 0.0618672 for infinitely many positive integers n, while it can also be shown via the same methods that L < -1.3892783 for infinitely many positive integers n.
For any, assuming the Riemann hypothesis, we have that the summatory function is bounded by
where the is some absolute limiting constant.
Define the related sum
It was open for some time whether T ≥ 0 for sufficiently big nn0. This was then disproved by, who showed that T takes negative values infinitely often. A confirmation of this positivity conjecture would have led to a proof of the Riemann hypothesis, as was shown by Pál Turán.

Generalizations

More generally, we can consider the weighted summatory functions over the Lioville function defined for any as follows for positive integers x where we have the special cases and
These -weighted summatory functions are related to the Mertens function, or weighted summatory functions of the Moebius function. In fact, we have that the so-termed non-weigthed, or ordinary function precisely corresponds to the sum
Moreover, as noted in these functions satisfy similar bounding asymptotic relations. For example, whenever, we see that there exists an absolute constant such that
By an application of Perron's formula, or equivalently by a key Mellin transform, we have that
which then can be inverted via the inverse transform to show that for, and
where we can take, and with the remainder terms defined such that and as.
In particular, if we assume that the
Riemann hypothesis is true and that all of the non-trivial zeros, denoted by, of the Riemann zeta function are simple, then for any and there exists an infinite sequence of which satisfies that for all v such that
where for any increasingly small we define
and where the remainder term
which of course tends to 0 as. These exact analytic formula expansions again share similar properties to those corresponding to the weighted Mertens function cases. Additionally, since we have another similarity in the form of to in so much as the dominant leading term in the previous formulas predicts a negative bias in the values of these functions over the positive natural numbers x.