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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What is a natural homomorphism from $G$ to $G\times H$?

Let $G$ and $H$ be two groups. What would a "natural homomorphism" from $G$ to $G\times H$ look like? My book mentions that one may assign natural homomorphisms from $G$ and $H$ to $G\times H$, but I don't understand the statement. Does it mean I…
freebird
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Transcendental, Algebraic

I just want to know: If a certain number is transcendental, call it $n$, is it safe to say that $n^2$ or that multiples of $n$ are are also transcendental? For example, from $e$ is transcendental, can we deduce that $e^2$ is transcendental?
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What's the difference between the associative law and the commutative law?

Both laws say that for some operations the order in which the calculation happens does not affect the result. Where is the difference exactly?
Lenar Hoyt
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Kernel of a substitution map

Suppose $R=k[x,y,z]$ and $S=k[t]$. Consider the map $f:R\to S$ s.t. $f(x)=t$, $f(y)=t^2$ and $f(z)=t^3$. I suspect the kernel of this map is the ideal $(y-x^2,z-x^3)R$. It's clearly contained in the kernel, but I am not sure how to prove the…
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Different version of Gauss's Lemma

Let $A$ be a domain with field of fractions $K$. Let $f, g \in A[X]$ with $g$ monic. Show that if $f/g \in K[X]$ then $f/g \in A[X]$. So I tried the direct approach by just assuming $f/g$ has a coefficient $a/b$ and then multiplying out with $g$…
Anna
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Applications of abstract algebra?

I'm currently learning abstract algebra in high school. The subject itself is extremely interesting because of its generality. I have found that it includes a lot of concepts that I have thought about before. For example, the whole concept of…
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Trying to understand $\mathbb{Q} / \mathbb{Z}$

If I'm not mistaken, $\mathbb{Q} / \mathbb{Z}$ are equivalence classes of rationals where $q \sim q^\prime$ iff they differ by an integer. So I could equally imagine this set as $\mathbb{Q} \cap [0,1]$ (mod 1) (if you know what I mean?). Is that the…
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Is there a use for this binary operation?

For any $a, b \in \mathbb{Z}$ define $a * b = a + b + 2ab$ I've seen this pop up a few times in exercises, and I'm wondering if there's a name for this (or any similar variants), and if it's ever useful.
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How to prove that the result of multiplying two number of the same set is in the same set?

I'm a chemist and I'm studying abstract algebra on my own so I don't know if this is a trivial question. If I have for example two number $a$ and $b$ (where $ a,b \in \mathbb{Q} $). How can I prove that $a \times b \in \mathbb{Q} $ ? Of course I'm…
G M
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Are there real algebras that don't have rational structure constants?

Take a finite dimensional associative algebra $A$ over the reals. Fix a basis $\{x_1, x_2, \ldots x_n\}$. The multiplication is completely specified by specifying structure constants $c^{ij}_k$ defined by the following equation: $$x_i \cdot x_j =…
Turion
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How is a "computer variable" defined mathematically?

Variables used in maths formulae are not the same that those of computing programs. Maths variables can be bound to a given value only once, and then keep that value. On the other hand, a programming variable is "mutable". It is like a box with a…
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Integral domain that is integrally closed, one-dimensional and not noetherian

I've tried to construct examples of rings that match all except one of the properties in the definition of a Dedekind domain. (This is an old number theory qual question from Berkeleys MGSA website). The only starting point that I can think of would…
dst
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Is isomorphism of two subgroups, one of them normal, enough to guarantee that the other is normal as well?

Let $G$ be a group and $H$, $K$ subgroups such that $H$ is normal in $G$ and $H$, $K$ are isomorphic. After some thought i intuitively concluded that $K$ is not necessarilly normal in $G$. Is that the case? Any rigorous argument? (e.g.…
Manos
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$ \Bbb Q [ \sqrt{2} + \sqrt{3} ] = \Bbb Q [ \sqrt{2} , \sqrt{3} ] $

Prove, that $ \Bbb Q [ \sqrt{2} + \sqrt{3} ] = \Bbb Q [ \sqrt{2} , \sqrt{3} ] $ I don't know the definition of $\Bbb Q [ \sqrt{2} , \sqrt{3} ]$, can anyone help me with this?
Kuba
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Finding $\gcd(x^2, x^3)$ inside $\mathbb{Z}[x^2,x^3]$

Let $R = \mathbb{Z}[x^2, x^3]$. Then $R$ contains all integer polynomials that lack the $x$ term. That is, $R$ contains all polynomials of form $a_0 + a_2 x^2 + a_3x^3 + \ldots + a_n x^n$ for $a_i \in \mathbb{Z}$. Question: What is $\gcd(x^2,…
Techn1cal
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