Groups having all elements off a normal subgroup with prime power order

Abstract

We consider a finite group G with a normal subgroup N so that all elements of G N have prime power order. We prove that if there is a prime p so that all the elements in G N have p-power order, then either G is a p-group or G = PN where P is a Sylow p-subgroup and (G,P,P N) is a Frobenius-Wielandt triple. We also prove that if all the elements of G N have prime power orders and the orders are divisible by two primes p and q, then G is a \ p, q \-group and G/N is either a Frobenius group or a 2-Frobenius group. If all the elements of G N have prime power orders and the orders are divisible by at least three primes, then all elements of G have prime power order and G/N is nonsolvable.