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.

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Analogy between $\Bbb F[x]$ and $\Bbb Z$?

Assume $\Bbb F$ is a field. Does the simplified form of $(x+1)^4$ in $\Bbb F[x]/(x^2-1)(x+1)$ have any connection to reducing $(a+1)^4$ in $\Bbb Z/(a^2-1)(a+1)$ and reducing $(a-1)^4$ in $\Bbb Z/(a^2-1)(a-1)$ where $a\in\Bbb N$ holds?
Turbo
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Idea behind defining a Projective System

What is the idea behind defined a Projective system of Groups/Rings. In our class an example for the Projective system was given by Taking the Ring $\mathbb{Z}/n\mathbb{Z}$ over $\mathbb{N}$. The order defined was: $ m \leq n$ if $m \mid…
anonymous
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If $p$ is prime, what is the difference between $F_p$, $\mathbb{Z}_p$ and $\mathbb{Z}/(p \mathbb{Z})$?

It's all in the title: $p$ is prime, what is the difference between $F_p$, $\mathbb{Z}_p$ and $\mathbb{Z}/(p \mathbb{Z})$? Also, if $p$ is not a prime, what is the difference between $\mathbb{Z}_p$ and $\mathbb{Z}/(p \mathbb{Z})$?
Sidious Lord
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Show that $x^2 + 1$ is irreducible over $\Bbb Z_3$ and reducible over $\Bbb Z_5$

Show that $x^2 + 1$ is irreducible over $\Bbb Z_3$ and reducible over $\Bbb Z_5$. I can't figure any way to express $x^2 + 1$ as a product of two polynomials in either ring. Each product I try either ends up with a number being off by $1$ or…
Oliver G
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How can i prove that the finite extension field of real number is itself or the field which is isomorphic to complex number?

How can i prove that the finite extension field of real number is itself or the field which is isomorphic to complex number ? In deed, this example is included in Fraleght . Abstract Algebra text. I did try the followings: $\mathbb{R}$ is real…
J.U.math
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Prime elements in $\mathbb{Z}/n\mathbb{Z}$

I'm tring to determine the prime elements in the ring $\mathbb{Z}/n\mathbb{Z}$.
Mykie
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Irreducible polynomial in $\mathbb{F}_{p}[x]$

I'm studing for an exam and I am stuck on the following practice problem. Consider the the ring $R=\mathbb{F}_{p}[x]$. How many irreducible polynomials of degree 4 exist in $R$?
Mykie
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Euler's theorem on a polynomial

The following theorem is said to be due to Euler. However, it seems not so well known. How do you prove this? Theorem Let $K$ be a field. Let $n \geq 1$ be an integer. Let $\alpha_1,\dots,\alpha_n$ be distinct elements of $K$. Let $f(X) = (X -…
Makoto Kato
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Listing down the Galois group

This is a common exercise: Sketch the lattice of subfields of $F = \mathbb{Q} ( \mathbb{e^{\frac{2 \pi i}{p}}})$ be a cyclotomic extension over $\mathbb{Q}$ (where $p$ is an odd prime). It got me wondering, what's the easiest way of…
buck
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If $f^*:\mathrm{Hom}(H, R) \to \mathrm{Hom}(G, R)$ is an iso for all $R$, is $f: G\to H$ an iso?

Let $G$, $H$ be abelian groups and $f: G\to H$ a homomorphism. Assume that $f^*: \mathrm{Hom}(H, R) \to \mathrm{Hom}(G, R)$ (as morphisms of abelian groups, taking $R$ with its additive group structure) is an isomorphism for all commutative rings…
blue
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Is there a binary operation satisfying these conditions?

Last night I started to read some book that has to do with applications of groups in physics and the question came in my mind about the existence of some structure, which I define in this way: Suppose that we have set $S$ which has at least…
Farewell
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Aut(GxH) isomorphic to Aut(G)xAut(H)

Can anyone help with the following proof? Let H,G be final groups. $(|G|,|H|) = 1$, prove that $Aut(G×H) ≅ Aut(G) ×Aut(H)$ I found this question Show that if $ \gcd(|G|,|H|) = 1 $, then $ \text{Aut}(G \times H) \cong \text{Aut}(G) \times…
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How do modules,vector spaces, algebras,fields,rings, groups, relate to one another?

Modules, vector spaces, algebras, fields, rings, groups... How do these basic algebraic objects relate to each other via tensor products? Is there a way to go from one object to its generalization via a tensor product construction? I think this is…
hello
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The Battleship Problem: sequences $x$ such that $\{tv+x_t\pmod n:x_t\in x\}=\mathbb{Z}_n$ for all $v \in \mathbb{Z}_n$.

A coworker posed this problem as "The Battleship Problem": A battleship starts at some unknown initial location $i\in\mathbb{Z}_n$ and moves at a constant velocity $v$ each turn. Each turn $t$ you may drop a bomb on one predetermined location, and…
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How do I show that $\overline{\mathbb{Q}} := \{\alpha \in \mathbb{C}\mid \alpha\text{ is algebraic over }\mathbb{Q} \}$ is algebraically closed?

How do I show that $\overline{\mathbb{Q}} := \{\alpha \in \mathbb{C}\mid \alpha\text{ is algebraic over }\mathbb{Q} \}$ is algebraically closed? I am thinking about solving this using that $\mathbb{C}$ is algebraically closed but I don't know hot to…