Lehmer conjecture

A conjecture about the minimal Mahler measure of a non-zero algebraic integer which is not a root of unity. The Mahler measure $M(\alpha)$ of an algebraic number $\alpha$ is defined by $$ M(\alpha) = a_0 \prod_{i=1}^N \max(1,|\alpha_i|) \ , $$ where $a_0$ denotes the leading coefficient and $N$ the degree of the minimal polynomial $f$ (with integral coefficients) of $\alpha$ (cf. also Algebraic number) and $\alpha=\alpha_1,\alpha_2,\ldots,\alpha_N$ are its conjugates. Since $M(\alpha)$ depends only on $f$, it is also denoted by $M(f)$ and called the Mahler measure of $f$. Jensen's formula (cf. also Jensen formula) implies the equality $$ M(f) = \exp\left({ \int_0^1 \log\left\vert{ f\left({ e^{2\pi i t} }\right) }\right\vert d t }\right) $$ and this observation permits one to generalize Mahler's measure to polynomials in several variables (see [a11], [a13]).

A theorem of L. Kronecker implies that if is an algebraic integer with , then is either zero or a root of unity. D.H. Lehmer [a7] asked whether could attain values arbitrarily close to . This subsequently led to the following formulation of Lehmer's conjecture: There exists a positive constant such that if is an algebraic integer, not a root of unity, then

Lehmer's conjecture is equivalent to the existence of ergodic automorphisms of the infinite-dimensional torus having finite entropy [a8] and its truth would imply the following conjecture stated by A. Schinzel and H. Zassenhaus [a16]: There exists a positive constant with the property that if is a non-zero algebraic integer of degree , not a root of unity, then , the maximal absolute value of a conjugate of is at least

It is known ([a2], [a14]) that Lehmer's conjecture holds for non-reciprocal integers , i.e. algebraic integers whose minimal polynomials do not have as a root. In this case the minimal value for equals and is attained by roots of the polynomial .

In 1971, P.E. Blanksby and H.L. Montgomery [a1] established, for all algebraic integers of degree that are not roots of unity, the inequality

and subsequently E. Dobrowolski [a4] obtained

with , whereas for he got . Subsequently, several authors increased the value of to ([a3], [a12]) and ([a9]). Since for non-reciprocal integers one has , the last result leads to the inequality

but this has been superseded by A. Dubickas [a5], who proved for sufficiently large the inequality

which is the strongest known result toward the Schinzel–Zassenhaus conjecture as of 2000.

The smallest known value of is , realized by the root of and found in [a7].

References