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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Prove that the centralizer is a normal subgroup.

Possible Duplicate: Prove that the center of a group is a normal subgroup Suppose that $H$ is a normal subgroup of $G$. Prove that $C_{G}(H)$ is a normal subgroup of $G$, where $C_{G}(H)$ is the centralizer of $H$ in $G$. I have proved that…
Mark
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Flat modules and its equivalent definitions

I was reading this Lang's book where he says F3: For every injection $0\rightarrow E'\rightarrow E$, we have $0\rightarrow E'\otimes F\rightarrow E\otimes F$ F1: For every exact sequence $E'\rightarrow E\rightarrow E''$, we have an exact sequence…
enoughsaid05
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Classify $(\mathbb{Z}_4 \times \mathbb{Z}_4 \times \mathbb{Z}_8) / <(1,2,4)>$ with the fundamental theorem of finitely generated abelian groups.

Since $|\mathbb{Z}_4 \times \mathbb{Z}_4 \times \mathbb{Z}_8| = 4\times 4 \times 8$ and $|<(1,2,4)>| = 4$ , $(\mathbb{Z}_4 \times \mathbb{Z}_4 \times \mathbb{Z}_8) / <(1,2,4)>$ is an abelian group of order 32. All abelian groups of order $32$…
최선웅
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Writing an Abelian group as a direct sum of cyclic groups given its presentation

Given the presentation of a finitely generated Abelian group, is there a straight forward way to write it as a direct sum of cyclic groups? The particular presentation I am looking at is $[a,b,c,d | a^3b^6c^{12}d^9, a^2b^6c^{10}d^8, a^2b^4c^8d^6]$
math4tots
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Hungerford Algebra Problem (Ch 1 Section 8)

I stuck on the following problem from Hungerford's Algebra. Let $H,K,N$ be normal in a group $G$ such that $G = H \times K$. Show $N$ is in the center of $G$ or intersects $H$ or $K$ non trivially. I tried to construct some type of group action…
Mykie
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Prove that G is Cyclic

Let $G$ be a group with of order 170 and $|Z(G)|$ divisible by 2. Prove that $G$ is cyclic. I'm thinking that I need to use Sylow's theorem in some way but I don't really know where to start. Appreciate any help!
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Let m be non-prime positive integer. Under what conditions on $m$ and $f\in \Bbb Z_m[x]$ will $\Bbb Z_m[x]/(f)$ be a field?

Let $m$ be a non-prime positive integer. Under what conditions on $m$ and $f\in \Bbb Z_m[x]$ will $\Bbb Z_m[x]/(f)$ be a field/integral domain? My obsevations: 1. When there exists some $a\in \Bbb Z$ such that f(a) (by viewing $f$ as polynomial in…
Loafy Loafer
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Given a Field $F$, and $a, b \in F$, show that the equation $a+x=b$ has a unique solution.

This is my first math problem set, and I am a little confused. This is my solution to the problem, however it think it might be a little too easy... I have a Field $F$ and $ a, b \in F$. I am supposed to show that the equation $ a + x = b $ has a…
padrino
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Ideals in localization of Dedekind domains

If $A$ is a Dedekind domain and $a,b$ are ideals, then why does $aA_p⊂bA_p$ for every prime ideal $p$ imply that $a\subset b$? I read it in Milne's notes but it alludes to DVR's and I'm not familiar with that concept.
user46225
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Are the roots of $\lambda^2-\lambda=0$ always the addition identity and multiplication identity for any field?

Are the roots of polynomial $\lambda^2-\lambda=0$ always the addition identity $0$ and multiplication identity $1$ for any field $F$? If not, anyone can help give a counterexample?
Tuyet
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Ring homomorphisms from the real polynomial ring to the real field

Let $\mathbb{R}[x]$ be the ring of polynomials with real coefficients in the determinate $x$. Each $\mathbb{R}$-algebra homomorphism from $\mathbb{R}[x]$ to $\mathbb{R}$ has the form $$ f(x) \mapsto f(\lambda) $$ for some $\lambda \in…
user17982
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Why are the first, second and third isomorphism theorems named as such?

I have taken introductory courses on groups, rings, fields and vector spaces and am currently taking one on modules. A common theme among such subjects are the three isomorphism theorems (as in, those found here…
user34832
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Is $x^6 + 3x^3 -2$ irreducible over $\mathbb Q$?

It seems that it is irreducible over $\mathbb Q$, I tried to apply Eisenstein's criterion to $f(x+a)$ for some $a$, but it didn't work. Also, I found a root $\alpha = \sqrt[3]{\frac{\sqrt{17}-3}{2}}$ and tried to prove that the degree of $\alpha$…
bellcircle
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Show that a commutative ring with unity having no proper ideals is a field

Show that a commutative ring with unity having no proper ideals is a field. No proper ideals means that $\{0\},R$ are the only ideals of $R$. But then $\{0\}$ is a maximal ideal and thus by applying the first isomorphism theorem we get that…
TheGeekGreek
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If $R$ is a nilpotent ring. Prove that if $N\not=0$ then $RN\not=N$.

I am working on the following problem. Let $R$ be a nilpotent ring (there exists a positive integer $n$ such that the product of $m$ elements of $R$ is $0$). Let $M$ be an $R$-module and $N$ any submodule of $M$. Prove that if $N\not=0$, then…
Matt
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