Questions tagged [abstract-algebra]

For questions about monoids, groups, rings, modules, fields, vector spaces, algebras over fields, various types of lattices, and other such algebraic objects. Associate with related tags like [group-theory], [ring-theory], [modules], etc. as necessary to clarify which topic of abstract algebra is most related to your question and help other users when searching.

Abstract algebra is the study of algebraic objects, i.e. sets endowed with one or more operations on the elements of those sets. In particular, the study of abstract algebra considers the algebraic structures and properties of which such operations induce. It can be considered as the generalization of the study of the algebraic structure of the integers and real numbers (arithmetic), or the study of matrices and vector spaces (linear algebra).

Some algebraic objects are monoids, groups, rings, fields, vector spaces, modules, algebras, and categories, among many other less prominent objects.

Examples

  1. The set of non-negative integers $\mathbb{N} = \{0,1,2,3,\dotsc\}$ is a monoid under the operation $+$.

  2. The integers $\mathbb{Z} = \{\dotsc,-1,0,1,\dotsc\}$ under the binary operation of $+$ form a group.

  3. Furthermore, $\mathbb{Z}$ has the structure of a ring when you consider it as being equipped with both addition and multiplication.

  4. The real numbers $\mathbb{R}$ with their usual addition and multiplication form a field.

  5. The set of $n\times n$ matrices with entries in $\mathbb{R}$ with matrix addition and multiplication form a ring.

  6. The set of $1\times n$ vectors over the real numbers, with vector addition, and multiplication by elements of the $n\times n$ real matrices on the right are an example of a module for the ring of matrices.

In addition to studying the objects themselves, abstract algebra considers homomorphisms between the objects and various constructions and tools, which are useful for studying the objects.

85022 questions
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Commutativity in rings of matrices

Let n be arbitrary positive integer and R arbitrary ring (perhaps, non-associative). Let's denote $M_n(R)$ the set of all $n х n$ matrices with entries from R. As i know if R is non-trivial commutative ring without zero divisors then scalar matrices…
Igor
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Every Principal Ideal Domain is a Unique Factorization Domain

I am interested in verifying the existence aspect of the theorem asserting that every Principal Ideal Domain is a Unique Factorization Domain. In the first paragraph, I (think that I) have provided an explanation for an arbitrary nonzero element $r$…
user74973
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Basic question about cyclic groups and Galois theory

Let $F/K$ be a finite extension and suppose $F$ is the splitting field of a separable polynomial over $K$. Show that if Gal(F/K) is cyclic then for each divisor $d$ of $[F : K]$ there exists exactly one subfield $E$ of $K \subseteq E \subseteq F$…
user6495
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Additive group of rational numbers

Let $\mathbb{Z}[\frac{1}{p}]$ be the additive group of rational numbers of the form $mp^n$ where $m$, $n$ are elements of $\mathbb{Z}$ and $p$ is a fixed prime. Describe $\text{End}(\mathbb{Z}[\frac{1}{p})]$ and…
user11116
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Rings with zero divisors

Is there a ring $~R~$ with non-trivial multiplication (i.e. $~\exists a,b\in R ~~~ ab\neq 0$) such that each non-zero element of $~R~$ is a zero-divisor?
Igor
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How can I show that $x^4+6$ is reducible over $\mathbb{R}$?

How can I show that the polynomial $x^4 + 6$ is reducible over $\mathbb{R}$ without explicitly finding factors? I was trying to find a non-prime ideal that would generate it but I'm kind of lost as to how to proceed. Is there some sort of criterion…
Danny
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complete the table by providing an example of a binary operation $*$ defined on $\{a , b ,c\}$

I have a problem with one of my questions. The question is: complete the table by providing an example of a binary operation $*$ defined on $\{a , b ,c\}$ such that $*$ is commutative and has the identity element $c$. \begin{array}{c|ccc} \ast & a &…
peter
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Is it always true that intersection of two Sylow p-subgroups is trivial?

I would like to investigate a few properties of Sylow p-subgroup, especially, when $p^n \;|\; |G|$ for $n > 1$. If $n = 1$ and $P_1, P_2$ are Sylow $p$-subgroups, then if $id \neq g \in P_1 \cap P_2$, then $\{g, \cdots, g^p\} = P_1 = P_2$, so the…
James C
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Normal subgroups of a group of order 12

Let $G$ be a group of order 12 and suppose $G$ does not have normal subgroups of order $4$. How to show that $G$ has a subgroup of order $6$?
user6495
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Does every element of an integral domain have an inverse?

I am reading a first course in algebra 7th edition written by John B. Fraleigh. I have seen the following two definitions: 1) A field is a commutative ring in which every nonzero element has multiplicative inverse. 2) An integral domain is a…
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What is an involutional automorphism?

I am reading a paper that is a little too advanced for me, and it has the following statement: $$ \text{There is a division ring } K \text{ with involutional automorphism } *: K \rightarrow K$$ I am struggling to find a proper definition of…
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$\frac{S}{mS}$ is isomorphic to $\frac{R}{mR}$, where m is coprime to n.

I am trying to prove the following statement: Let R be a commutative ring with a unit element, and S be a subring of R of finite index n. Then $\frac{S}{mS}$ is isomorphic to $\frac{R}{mR}$, where m is coprime to n. I have no idea how I should use…
awr
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Fundamental theorem of Galois Theory problem

I am trying to understand this problem. Part of it says Let $K/F$ be any finite extension and let $\alpha \in K$. Let $L$ be a Galois extension of $F$ containing $K$ and let $H \leq Gal(L/F)$ be the subgroup corresponding to $K$. Define the norm…
badatmath
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Question about Galois theory (separable polynomial)

One of the definitions of a Galois extension is that $E/K$ is Galois iff $E$ is the splitting field of some separable polynomial $f(x) \in K[x]$, yes? I want to understand why the following is true: Let $f(x) \in \mathbb{Q}[x]$ be a polynomial and…
user6495
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For each positive integer $n$ prove that $\textbf{C}^{*}$ the group of nonzero complex numbers under multiplication

For each positive integer $n$ prove that $\textbf{C}^{*}$ the group of nonzero complex numbers under multiplication , has exactly $\phi(n)$ elements of order $n$. Where $\phi$ is totient function. I was thinking about this problem and my answer…
user828395