Let G be a finite group with order g and S be a subring of the algebraic number field which contains the integral extension over Z generated by a g-th primitive root co of unity, and R(G) be the character ring of G....Let G be a finite group with order g and S be a subring of the algebraic number field which contains the integral extension over Z generated by a g-th primitive root co of unity, and R(G) be the character ring of G. The prime spectrum of the commutative ring S×Z R(G) iv denoted by Spec(S×Z R(G)) and set π={p|p is a rational prime number such that p^-1 S}. We prove that when G is a regroup, a π'-group, or a finite Abelian group, the number of the connetted components of Spec( S×Z R (G) ) coincides with the number of the π-regular classes in G,展开更多
文摘Let G be a finite group with order g and S be a subring of the algebraic number field which contains the integral extension over Z generated by a g-th primitive root co of unity, and R(G) be the character ring of G. The prime spectrum of the commutative ring S×Z R(G) iv denoted by Spec(S×Z R(G)) and set π={p|p is a rational prime number such that p^-1 S}. We prove that when G is a regroup, a π'-group, or a finite Abelian group, the number of the connetted components of Spec( S×Z R (G) ) coincides with the number of the π-regular classes in G,
