Finite group extensions and the Atiyah conjecture

The Atiyah conjecture for a discrete group $ G$ states that the $ L^2ehBBetti numbers of a finite CW-complex with fundamental group $ G$ are integers if $ G$ is torsion-free, and in general that they are rational numbers with denominators determined by the finite subgroups of $ G$. Here we establish conditions under which the Atiyah conjecture for a torsion-free group $ G$ implies the Atiyah conjecture for every finite extension of $ G$. The most important requirement is that $ H^ (G,\mathbb{Z}/p)$ is isomorphic to the cohomology of the $ pehBadic completion of $ G$ for every prime number $ p$. An additional assumption is necessary e.g. that the quotients of the lower central series or of the derived series are torsion-free. We prove that these conditions are fulfilled for a certain class of groups, which contains in particular Artin's pure braid groups (and more generally fundamental groups of fiber-type arrangements), free groups, fundamental groups of orientable compact surfaces, certain knot and link groups, certain primitive one-relator groups, and products of these. Therefore every finite, in fact every elementary amenable extension of these groups satisfies the Atiyah conjecture, provided the group does. As a consequence, if such an extension $ H$ is torsion-free, then the group ring $ \mathbb{C}H$ contains no non-trivial zero divisors, i.e. $ H$ fulfills the zero-divisor conjecture. In the course of the proof we prove that if these extensions are torsion-free, then they have plenty of non-trivial torsion-free quotients which are virtually nilpotent. All of this applies in particular to Artin's full braid group, therefore answering question B6 on http://www.grouptheory.info. Our methods also apply to the Baum-Connes conjecture. This is discussed by Thomas Schick in his preprint ``Finite group extensions and the Baum-Connes conjecture'', where for example the Baum-Connes conjecture is proved for the full braid groups.