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In mathematics, if A is an associative algebra over K, then an element a of A is called an algebraic element over K, or just algebraic over K, if there exists some non-zero polynomial ${\displaystyle g(x)\in K}$ with coefficients in K such that g(a) = 0. Elements of A that are not algebraic over K are called transcendental over K. A special case of an associative algebra over ${\displaystyle K}$ is an extension field ${\displaystyle L}$ of ${\displaystyle K}$.

These notions generalize the algebraic numbers and the transcendental numbers (where the field extension is C/Q, with C being the field of complex numbers and Q being the field of rational numbers).

Examples

• The square root of 2 is algebraic over Q, since it is the root of the polynomial g(x) = x − 2 whose coefficients are rational.
• Pi is transcendental over Q but algebraic over the field of real numbers R: it is the root of g(x) = x − π, whose coefficients (1 and −π) are both real, but not of any polynomial with only rational coefficients. (The definition of the term transcendental number uses C/Q, not C/R.)

Properties

The following conditions are equivalent for an element ${\displaystyle a}$ of an extension field ${\displaystyle L}$ of ${\displaystyle K}$:

• ${\displaystyle a}$ is algebraic over ${\displaystyle K}$,
• the field extension ${\displaystyle K(a)/K}$ is algebraic, i.e. every element of ${\displaystyle K(a)}$ is algebraic over ${\displaystyle K}$ (here ${\displaystyle K(a)}$ denotes the smallest subfield of ${\displaystyle L}$ containing ${\displaystyle K}$ and ${\displaystyle a}$),
• the field extension ${\displaystyle K(a)/K}$ has finite degree, i.e. the dimension of ${\displaystyle K(a)}$ as a ${\displaystyle K}$-vector space is finite,
• ${\displaystyle K=K(a)}$, where ${\displaystyle K}$ is the set of all elements of ${\displaystyle L}$ that can be written in the form ${\displaystyle g(a)}$ with a polynomial ${\displaystyle g}$ whose coefficients lie in ${\displaystyle K}$.

To make this more explicit, consider the polynomial evaluation ${\displaystyle \varepsilon _{a}:K\rightarrow K(a),\,P\mapsto P(a)}$. This is a homomorphism and its kernel is ${\displaystyle \{P\in K\mid P(a)=0\}}$. If ${\displaystyle a}$ is algebraic, this ideal contains non-zero polynomials, but as ${\displaystyle K}$ is a euclidean domain, it contains a unique polynomial ${\displaystyle p}$ with minimal degree and leading coefficient ${\displaystyle 1}$, which then also generates the ideal and must be irreducible. The polynomial ${\displaystyle p}$ is called the minimal polynomial of ${\displaystyle a}$ and it encodes many important properties of ${\displaystyle a}$. Hence the ring isomorphism ${\displaystyle K/(p)\rightarrow \mathrm {im} (\varepsilon _{a})}$ obtained by the homomorphism theorem is an isomorphism of fields, where we can then observe that ${\displaystyle \mathrm {im} (\varepsilon _{a})=K(a)}$. Otherwise, ${\displaystyle \varepsilon _{a}}$ is injective and hence we obtain a field isomorphism ${\displaystyle K(X)\rightarrow K(a)}$, where ${\displaystyle K(X)}$ is the field of fractions of ${\displaystyle K}$, i.e. the field of rational functions on ${\displaystyle K}$, by the universal property of the field of fractions. We can conclude that in any case, we find an isomorphism ${\displaystyle K(a)\cong K/(p)}$ or ${\displaystyle K(a)\cong K(X)}$. Investigating this construction yields the desired results.

This characterization can be used to show that the sum, difference, product and quotient of algebraic elements over ${\displaystyle K}$ are again algebraic over ${\displaystyle K}$. For if ${\displaystyle a}$ and ${\displaystyle b}$ are both algebraic, then ${\displaystyle (K(a))(b)}$ is finite. As it contains the aforementioned combinations of ${\displaystyle a}$ and ${\displaystyle b}$, adjoining one of them to ${\displaystyle K}$ also yields a finite extension, and therefore these elements are algebraic as well. Thus set of all elements of ${\displaystyle L}$ that are algebraic over ${\displaystyle K}$ is a field that sits in between ${\displaystyle L}$ and ${\displaystyle K}$.

Fields that do not allow any algebraic elements over them (except their own elements) are called algebraically closed. The field of complex numbers is an example. If ${\displaystyle L}$ is algebraically closed, then the field of algebraic elements of ${\displaystyle L}$ over ${\displaystyle K}$ is algebraically closed, which can again be directly shown using the characterisation of simple algebraic extensions above. An example for this is the field of algebraic numbers.

See also

• Algebraic independence

References

1. Roman, Steven (2008). "18". Advanced Linear Algebra. Graduate Texts in Mathematics. New York, NY: Springer New York Springer e-books. pp. 458–459. ISBN 978-0-387-72831-5.

• Lang, Serge (2002), Algebra, Graduate Texts in Mathematics, vol. 211 (Revised third ed.), New York: Springer-Verlag, ISBN 978-0-387-95385-4, MR 1878556, Zbl 0984.00001

• Abstract algebra