Nigel Boston, Michael R. Bush, Farshid Hajir
Published 2011-11-20, updated 2014-12-10Version 2
Cohen and Lenstra have given a heuristic which, for a fixed odd prime $p$, leads to many interesting predictions about the distribution of $p$-class groups of imaginary quadratic fields. We extend the Cohen-Lenstra heuristic to a non-abelian setting by considering, for each imaginary quadratic field $K$, the Galois group of the $p$-class tower of $K$, i.e. $G_K:=\mathrm{Gal}(K_\infty/K)$ where $K_\infty$ is the maximal unramified $p$-extension of $K$. By class field theory, the maximal abelian quotient of $G_K$ is isomorphic to the $p$-class group of $K$. For integers $c\geq 1$, we give a heuristic of Cohen-Lentra type for the maximal $p$-class $c$ quotient of $\G_K$ and thereby give a conjectural formula for how frequently a given $p$-group of $p$-class $c$ occurs in this manner. In particular, we predict that every finite Schur $\sigma$-group occurs as $G_K$ for infinitely many fields $K$. We present numerical data in support of these conjectures.
Comments: Revised Version. Section 2 has been reorganized and divided into five subsections; the main results appear in Section 2.4. The numerical data has been greatly expanded using a modified technique of computing generating polynomials for unramified cubic extensions of imaginary quadratic fields
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