ABSTRACT
The study of automorphisms of algebraic structures has contributed immensely to
many important findings in mathematics. For example, Galois characterized the general
degree five single variable polynomials f over Q, by showing that the roots of such polynomials
cannot be expressed in terms of radicals, through the automorphism groups of
the splitting field of f. On the other hand, the symmetries of any algebraic structure are
captured by their automorphism groups. The study of completely primary finite rings has
shown their fundamental importance in the structure theory of finite rings with identity.
Quite reasonable research has been done towards characterization of the unit groups, R
of certain classes of finite commutative completely primary rings. Much less known however,
is whether there is a complete description of R, up to isomorphism. The existing
literature is still scanty on the characterization of Aut(R), the automorphism groups of
the unit groups of these classes of rings. Therefore, in this thesis, we have characterized
the structures and orders of the automorphisms of the unit groups of three classes of
commutative completely primary finite rings, that is, Square radical zero, Cube radical
zero and power Four radical zero finite commutative completely primary rings. The unit
groups of the classes of rings studied are expressible as R = Zpr−1 × (1 + J) such that,
Zpr−1 and (1 + J) are of relatively prime orders, where (1 + J) is a normal subgroup of
R and J is the Jacobson radical of R. We have expressed the structures of Aut(R) as
direct products of (Zpr−1) and GLrk(1+J)(Fp). We have made use of the invertible matrix
approach, the properties of diagonal matrices and determinants to count the number of
automorphisms of (1+J). We have then adjoined the counted Aut(1+J) to '((Zpr−1)),
where ' is the Euler’s phi-function, in order to completely characterize the order Aut(R).
Moreover, we have made use of the First Isomorphism Theorem to establish the relationship
between | GLrk(1+J)(Fp) | and | SLrk(1+J)(Fp) |. We noticed that our automorphisms
yielded very unique structure and order formulae, distinct from the well known structures
and order formulae of the automorphisms of the cyclic groups Cn. The results obtained
in this thesis contribute significantly to the existing literature on the structure theory of
finite rings with identity, thereby providing a much needed, accessible modern treatment
and a complete characterization of these classes of rings up to isomorphism.
OJIEMA, M (2021). Automorphisms Of The Unit Groups Of Square Radical Zero, Cube Radical Zero And Power Four Radical Zero Finite Commutative Completely Primary Rings. Afribary. Retrieved from https://track.afribary.com/works/automorphisms-of-the-unit-groups-of-square-radical-zero-cube-radical-zero-and-power-four-radical-zero-finite-commutative-completely-primary-rings
OJIEMA, MICHAEL "Automorphisms Of The Unit Groups Of Square Radical Zero, Cube Radical Zero And Power Four Radical Zero Finite Commutative Completely Primary Rings" Afribary. Afribary, 07 May. 2021, https://track.afribary.com/works/automorphisms-of-the-unit-groups-of-square-radical-zero-cube-radical-zero-and-power-four-radical-zero-finite-commutative-completely-primary-rings. Accessed 27 Nov. 2024.
OJIEMA, MICHAEL . "Automorphisms Of The Unit Groups Of Square Radical Zero, Cube Radical Zero And Power Four Radical Zero Finite Commutative Completely Primary Rings". Afribary, Afribary, 07 May. 2021. Web. 27 Nov. 2024. < https://track.afribary.com/works/automorphisms-of-the-unit-groups-of-square-radical-zero-cube-radical-zero-and-power-four-radical-zero-finite-commutative-completely-primary-rings >.
OJIEMA, MICHAEL . "Automorphisms Of The Unit Groups Of Square Radical Zero, Cube Radical Zero And Power Four Radical Zero Finite Commutative Completely Primary Rings" Afribary (2021). Accessed November 27, 2024. https://track.afribary.com/works/automorphisms-of-the-unit-groups-of-square-radical-zero-cube-radical-zero-and-power-four-radical-zero-finite-commutative-completely-primary-rings