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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Simple Algebraic Extension Divisibility

I've been trying to come up with a simple algebraic extension $F(\alpha)$ over a field $F$ that has $[F(\alpha):F]$ not divisible by 3, but has $F(\alpha^3)$ properly contained in $F(\alpha)$. I haven't had any luck - maybe I'm thinking…
Frank White
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Differences between homomorphisms and functions

Incredibly, I haven't been able to find a good entry online comparing these two mathematical structures. Their relative familiarity doesn't make their boundaries less fuzzy. Here is a coarse attempt: From Wikipedia, In mathematics, a function is a…
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Spivak Prologue Question: Basic Properties of Numbers

The Set Up I do not see how property 6 (P6) proves the assertion that $1 \neq 0$. Spivak gives 6 properties of numbers before asserting this fact, followed by the statement that "there is no way it could possibly be proved on the basis of the other…
aa.harithy
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Find whether $U(\mathbb{Z}_2[x]/\langle x^4\rangle )$ is a cyclic group

I have the following question: "Is $U(\mathbb{Z}_2[x]/\langle x^{4}\rangle )$ a cyclic group ." Attempt: I managed to show that it isn't a cyclic group by writing down all of its elements and computing their order. Is there a quicker way to…
1123581321
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Show that all elements in the conjugacy class of $\sigma$ in $S_n$ are conjugate in $A_n$ if and only if $\sigma$ commutes with an odd permutation.

Let $\sigma\in A_n$. Show that all elements in the conjugacy class of $\sigma$ in $S_n$ (i.e. all elements of the same cycle type as $\sigma$) are conjugate in $A_n$ if and only if $\sigma$ commutes with an odd permutation. Hint: Use the previous…
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Let $G$ be a cyclic (or not) group of order $n$ and let $k$ be an integer relatively prime to $n$. Prove that the map $x \mapsto x^k$ is surjective.

Let $G$ be a cyclic group of order $n$ and let $k$ be an integer relatively prime to $n$. Prove that the map $x \mapsto x^k$ is surjective. Use Lagrange's Theorem (Exercise 19, Section 1.7) to prove the same is true for any finite group of order…
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Prove that $\langle x^2+1\rangle$ is a maximal ideal of $\Bbb R[x]$

I'm trying to prove that $\langle x^2+1\rangle$ is a maximal ideal of $\Bbb R[x]$, but I have trouble. Let $I=\langle x^2+1\rangle$ and $R=\Bbb R[x]$. First, $I\neq R$. Second, let $J$ be any ideal of $R$ such that $I\subseteq J$. Suppose $J\neq I$,…
Eric
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Subgroups and ideals of integer numbers.

Let $(\mathbb{Z},+)$ be the additive group of integers, and $(\mathbb{Z}, +, \cdot)$ the ring of integers. By definition, every ideal of $(\mathbb{Z}, +, \cdot)$ is a subgroup of $(\mathbb{Z},+)$. Is the opposite true? Is every subgroup of…
bateman
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Ideals and generators being irreducible

I am working on this problem and I was wondering if anyone would be able to help me with it. The problem states:"Let F be a field and let J be an ideal in F[x]. Prove that J is prime if its generator is irreducible over F." I am not sure what…
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How can this isomorphism be valid?

How can $\mathbb{Z}_4 \times \mathbb{Z}_6 / <(2,3)> \cong \mathbb{Z}_{12} = \mathbb{Z}_{4} \times \mathbb{Z}_{3}$? I am not convinced at the least that $\mathbb{Z}_{12}$ is isomorphic to $\mathbb{Z}_4 \times \mathbb{Z}_6 / <(2,3)>$ For instance,…
Lemon
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Find all of the solutions to $[x]^{2}+[9][x]-[10]=[0]$ in the ring $\Bbb Z _{12}$

Find all of the solutions to $[x]^{2}+[9][x]-[10]=[0]$ in the ring $\Bbb Z _{12}$ So i know there are 4 of them. So i started out with 1 is a solution: $1^{2}+9(1)-10=0$ $\Rightarrow$ 10-10=0 $\Rightarrow$ 0=0 but then i realized you have to use…
MRI
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Using the natural homomorphism $\mathbb Z$ to $\mathbb Z_5$

Prove that $x^4+10x^3+7$ is irreducible in $\mathbb Q[x]$ by using the natural homomorphism from $\mathbb Z$ to $\mathbb Z_5$. So I would assume we should rewrite our polynomial, maybe as $(x + 10) x^3 + 7$? Then in terms of $\mathbb Z_5,…
K Math
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Computing an explicit square root in $\mathbb{Z}/p\mathbb{Z}$

Let $p=3 \ (mod \ 4)$ and assume $a$ is a square in $\mathbb Z/p \mathbb Z $. Compute an explicit square root of $a$. I am confused when it gives us that $p$ is modulo 4. How is this any different from saying that $p=3$? I know we are supposed to…
RZB
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$Ass(M) = Ass(N) \cup Ass(M/N)?$

Suppose $M$ is an $R$ module and $N$ is a submodule of $M.$ I am trying to prove the following: $Ass(M) = Ass(N) \cup Ass(M/N)$. This seemed intuitively true but the proof proved to be difficult. If I have a prime ideal $P \in Ass(M)$ then $P =…
green frog
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How do I embed $M/(N \cap N')$ as a submodule of $(M/N) \oplus (M/N')$?

How do I embed $M/(N \cap N')$ as a submodule of $(M/N) \oplus(M/N')$? My thought it the following... Simply send $m + N \cap N'$ to $(m + N, m + N').$ There is no ambiguity as $N \cap N'$ is a submodule of both $N$ and $N'.$ It is also injective by…
green frog
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