On the radical idealizer chain of symmetric orders
arXiv:math/0310191
Abstract
If $Î$ is an indecomposable, non maximal, symmetric order, then the idealizer of the radical $Î:= \Id(J(Î)) = J(Î)^{#} $ is the dual of the radical. If $Î$ is hereditary then $Î$ has a Brauer tree (under modest additional assumptions). Otherwise $Î:= \Id(J(Î)) = (J(Î)^2)^{#} $. If $Î= \Z_p G$ for a $p$-group $G\neq 1$, then $Î$ is hereditary iff $G\cong C_p$ and otherwise $[Î: Î] = p^2 | G/(G'G^p)| $. For Abelian groups $G$, the length of the radical idealizer chain of $\Z_pG$ is $(n-a)(p^{a} - p^{a-1})+p^{a-1}$, where $p^n$ is the order and $p^a$ the exponent of the Sylow $p$-subgroup of $G$.