Key Definitions

Key Definitions in Abstract Algebra

Group Theory

Basic Concepts

Group: An ordered pair $(G, \cdot)$ where $G$ is a non-empty set and $\cdot$ is a binary operation satisfying:

Closure: $a \cdot b \in G$ for all $a, b \in G$
Associativity: $(a \cdot b) \cdot c = a \cdot (b \cdot c)$
Identity: There exists $e \in G$ such that $e \cdot a = a \cdot e = a$
Inverses: For each $a \in G$ , there exists $a^{- 1} \in G$ such that $a \cdot a^{- 1} = a^{- 1} \cdot a = e$

Abelian Group: A group where the operation is commutative: $a \cdot b = b \cdot a$ for all $a, b \in G$

Order of a Group: The number of elements in a finite group, denoted $| G |$

Order of an Element: The smallest positive integer $n$ such that $g^{n} = e$ , denoted $| g |$

Subgroups

Subgroup: A non-empty subset $H$ of a group $G$ that forms a group under the same operation, denoted $H \leq G$

Normal Subgroup: A subgroup $N$ of $G$ such that $g N g^{- 1} = N$ for all $g \in G$ , denoted $N ⊴ G$

Quotient Group: The group $G / N$ of cosets of a normal subgroup $N$ in $G$

Homomorphisms

Group Homomorphism: A map $ϕ : G \to H$ such that $ϕ (g_{1} g_{2}) = ϕ (g_{1}) ϕ (g_{2})$

Isomorphism: A bijective homomorphism, denoted $G ≅ H$

Kernel: $\ker (ϕ) = {g \in G ∣ ϕ (g) = e_{H}}$

Image: $Im (ϕ) = {ϕ (g) ∣ g \in G}$

Special Groups

Cyclic Group: A group generated by a single element, denoted $⟨ g ⟩$

Dihedral Group: The symmetry group of a regular $n$ -gon, denoted $D_{n}$

Symmetric Group: The group of all permutations of $n$ elements, denoted $S_{n}$

Alternating Group: The subgroup of $S_{n}$ consisting of even permutations, denoted $A_{n}$

Simple Group: A group with no non-trivial normal subgroups

Ring Theory

Basic Concepts

Ring: A set $R$ with two operations $(+, \cdot)$ such that:

$(R, +)$ is an abelian group
$(R, \cdot)$ is a monoid
Multiplication distributes over addition

Commutative Ring: A ring where multiplication is commutative

Ring with Identity: A ring containing a multiplicative identity element $1$

Zero Divisor: An element $a \neq 0$ such that $a b = 0$ for some $b \neq 0$

Special Types of Rings

Integral Domain: A commutative ring with identity and no zero divisors

Field: A commutative ring with identity where every non-zero element has a multiplicative inverse

Division Ring: A ring with identity where every non-zero element has a multiplicative inverse (not necessarily commutative)

Ideals

Ideal: A subset $I$ of a ring $R$ such that:

$(I, +)$ is a subgroup of $(R, +)$
For all $r \in R$ and $x \in I$ , both $r x$ and $x r$ are in $I$

Principal Ideal: An ideal generated by a single element, denoted $(a)$

Prime Ideal: A proper ideal $P$ such that if $a b \in P$ , then either $a \in P$ or $b \in P$

Maximal Ideal: A proper ideal $M$ such that there is no ideal $I$ with $M \subset I \subset R$

Quotient Ring: The ring $R / I$ of cosets of an ideal $I$ in $R$

Special Domains

Principal Ideal Domain (PID): An integral domain where every ideal is principal

Euclidean Domain: An integral domain with a Euclidean function (division algorithm)

Unique Factorization Domain (UFD): An integral domain where every element has a unique factorization into irreducibles

Field Theory

Field Extensions

Field Extension: A pair of fields $L / K$ where $K$ is a subfield of $L$

Degree of Extension: The dimension of $L$ as a $K$ -vector space, denoted $[L : K]$

Finite Extension: An extension of finite degree

Algebraic Element: An element $α \in L$ that is a root of some non-zero polynomial in $K [x]$

Transcendental Element: An element that is not algebraic

Minimal Polynomial: The monic irreducible polynomial in $K [x]$ of which $α$ is a root

Special Extensions

Normal Extension: An extension where every irreducible polynomial in $K [x]$ with a root in $L$ splits completely in $L$

Separable Extension: An extension where every element is separable (its minimal polynomial has no repeated roots)

Galois Extension: An extension that is both normal and separable

Splitting Field: The smallest field extension of $K$ in which a polynomial splits completely

Galois Theory

Galois Groups

Galois Group: The group of all automorphisms of a Galois extension $L / K$ that fix $K$ , denoted $Gal (L / K)$

Fixed Field: The subfield of $L$ fixed by a subgroup $H$ of $Gal (L / K)$ , denoted $L^{H}$

Solvability

Solvable Group: A group with a composition series whose factors are all abelian

Solvable by Radicals: A polynomial whose roots can be expressed using arithmetic operations and roots

Radical Extension: An extension obtained by adjoining roots

Module Theory

Modules

Module: An abelian group $M$ with a scalar multiplication $R \times M \to M$ satisfying certain axioms

Free Module: A module with a basis

Finitely Generated Module: A module generated by a finite set

Torsion Module: A module where every element has finite order

Torsion-Free Module: A module with no non-zero torsion elements

Polynomial Theory

Polynomials

Irreducible Polynomial: A polynomial that cannot be factored into non-constant polynomials

Primitive Polynomial: A polynomial whose coefficients have greatest common divisor 1

Content: The greatest common divisor of the coefficients of a polynomial

Eisenstein's Criterion: A sufficient condition for irreducibility of polynomials

Algebraic Geometry

Basic Concepts

Algebraic Set: The zero locus of a set of polynomials

Variety: An irreducible algebraic set

Coordinate Ring: The ring of polynomial functions on an algebraic set

Ideal of a Set: The ideal of polynomials vanishing on a set

Radical Ideal: An ideal equal to its own radical

Advanced Concepts

Infinite Galois Theory

Profinite Group: A topological group that is compact, Hausdorff, and totally disconnected

Krull Topology: The topology on an infinite Galois group

Transcendence Theory

Algebraically Independent: A set of elements that do not satisfy any non-trivial polynomial equation

Transcendence Basis: A maximal algebraically independent set

Transcendence Degree: The cardinality of a transcendence basis

Algebraic Closures

Algebraically Closed Field: A field where every non-constant polynomial has a root

Algebraic Closure: A minimal algebraically closed extension of a field

Historical Context

These definitions represent the evolution of abstract algebra from the 19th century to the present day. The concepts were developed to solve problems in:

Number theory
Geometry
Analysis
Cryptography
Physics

The definitions provide a unified language for studying algebraic structures across mathematics and its applications.