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In
mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...
, an algebraic number field (or simply number field) is an
extension field In mathematics, particularly in algebra, a field extension is a pair of fields E\subseteq F, such that the operations of ''E'' are those of ''F'' restricted to ''E''. In this case, ''F'' is an extension field of ''E'' and ''E'' is a subfield of ...
K of the
field Field may refer to: Expanses of open ground * Field (agriculture), an area of land used for agricultural purposes * Airfield, an aerodrome that lacks the infrastructure of an airport * Battlefield * Lawn, an area of mowed grass * Meadow, a grass ...
of
rational number In mathematics, a rational number is a number that can be expressed as the quotient or fraction of two integers, a numerator and a non-zero denominator . For example, is a rational number, as is every integer (e.g. ). The set of all ration ...
s such that the field extension K / \mathbb has finite degree (and hence is an algebraic field extension). Thus K is a field that contains \mathbb and has finite
dimension In physics and mathematics, the dimension of a Space (mathematics), mathematical space (or object) is informally defined as the minimum number of coordinates needed to specify any Point (geometry), point within it. Thus, a Line (geometry), lin ...
when considered as a
vector space In mathematics and physics, a vector space (also called a linear space) is a set whose elements, often called ''vectors'', may be added together and multiplied ("scaled") by numbers called '' scalars''. Scalars are often real numbers, but can ...
over The study of algebraic number fields, and, more generally, of algebraic extensions of the field of rational numbers, is the central topic of
algebraic number theory Algebraic number theory is a branch of number theory that uses the techniques of abstract algebra to study the integers, rational numbers, and their generalizations. Number-theoretic questions are expressed in terms of properties of algebraic ob ...
. This study reveals hidden structures behind usual rational numbers, by using algebraic methods.


Definition


Prerequisites

The notion of algebraic number field relies on the concept of a
field Field may refer to: Expanses of open ground * Field (agriculture), an area of land used for agricultural purposes * Airfield, an aerodrome that lacks the infrastructure of an airport * Battlefield * Lawn, an area of mowed grass * Meadow, a grass ...
. A field consists of a
set Set, The Set, SET or SETS may refer to: Science, technology, and mathematics Mathematics *Set (mathematics), a collection of elements *Category of sets, the category whose objects and morphisms are sets and total functions, respectively Electro ...
of elements together with two operations, namely
addition Addition (usually signified by the Plus and minus signs#Plus sign, plus symbol ) is one of the four basic Operation (mathematics), operations of arithmetic, the other three being subtraction, multiplication and Division (mathematics), division. ...
, and
multiplication Multiplication (often denoted by the cross symbol , by the mid-line dot operator , by juxtaposition, or, on computers, by an asterisk ) is one of the four elementary mathematical operations of arithmetic, with the other ones being additi ...
, and some distributivity assumptions. A prominent example of a field is the field of
rational number In mathematics, a rational number is a number that can be expressed as the quotient or fraction of two integers, a numerator and a non-zero denominator . For example, is a rational number, as is every integer (e.g. ). The set of all ration ...
s, commonly denoted together with its usual operations of addition and multiplication. Another notion needed to define algebraic number fields is
vector space In mathematics and physics, a vector space (also called a linear space) is a set whose elements, often called ''vectors'', may be added together and multiplied ("scaled") by numbers called '' scalars''. Scalars are often real numbers, but can ...
s. To the extent needed here, vector spaces can be thought of as consisting of sequences (or
tuple In mathematics, a tuple is a finite ordered list (sequence) of elements. An -tuple is a sequence (or ordered list) of elements, where is a non-negative integer. There is only one 0-tuple, referred to as ''the empty tuple''. An -tuple is defi ...
s) :(''x''1, ''x''2, …) whose entries are elements of a fixed field, such as the field Any two such sequences can be added by adding the entries one per one. Furthermore, any sequence can be multiplied by a single element ''c'' of the fixed field. These two operations known as
vector addition In mathematics, physics, and engineering, a Euclidean vector or simply a vector (sometimes called a geometric vector or spatial vector) is a geometric object that has magnitude (or length) and direction. Vectors can be added to other vectors a ...
and
scalar multiplication In mathematics, scalar multiplication is one of the basic operations defining a vector space in linear algebra (or more generally, a module in abstract algebra). In common geometrical contexts, scalar multiplication of a real Euclidean vector b ...
satisfy a number of properties that serve to define vector spaces abstractly. Vector spaces are allowed to be "infinite-dimensional", that is to say that the sequences constituting the vector spaces are of infinite length. If, however, the vector space consists of ''finite'' sequences :(''x''1, ''x''2, …, ''x''''n''), the vector space is said to be of finite
dimension In physics and mathematics, the dimension of a Space (mathematics), mathematical space (or object) is informally defined as the minimum number of coordinates needed to specify any Point (geometry), point within it. Thus, a Line (geometry), lin ...
, ''n''.


Definition

An algebraic number field (or simply number field) is a finite-
degree Degree may refer to: As a unit of measurement * Degree (angle), a unit of angle measurement ** Degree of geographical latitude ** Degree of geographical longitude * Degree symbol (°), a notation used in science, engineering, and mathematics ...
field extension of the field of rational numbers. Here degree means the dimension of the field as a vector space over


Examples

* The smallest and most basic number field is the field of rational numbers. Many properties of general number fields are modeled after the properties of At the same time, many other properties of algebraic number fields are substantially different from the properties of rational numbers - one notable example is that the ring of algebraic integers of a number field is not a principal ideal domain, in general. * The
Gaussian rational In mathematics, a Gaussian rational number is a complex number of the form ''p'' + ''qi'', where ''p'' and ''q'' are both rational numbers. The set of all Gaussian rationals forms the Gaussian rational field, denoted Q(''i''), obtained by ...
s, denoted \mathbb(i) (read as "\mathbb adjoined i"), form the first (historically) non-trivial example of a number field. Its elements are elements of the form a + bi where both ''a'' and ''b'' are rational numbers and ''i'' is the
imaginary unit The imaginary unit or unit imaginary number () is a solution to the quadratic equation x^2+1=0. Although there is no real number with this property, can be used to extend the real numbers to what are called complex numbers, using addition an ...
. Such expressions may be added, subtracted, and multiplied according to the usual rules of arithmetic and then simplified using the identity i^2 = -1. Explicitly, \begin (a + bi) + (c + di) &=& (a + c) + (b + d)i \\ (a + bi)\cdot (c + di) &=& (ac - bd) + (ad + bc)i \end Non-zero Gaussian rational numbers are
invertible In mathematics, the concept of an inverse element generalises the concepts of opposite () and reciprocal () of numbers. Given an operation denoted here , and an identity element denoted , if , one says that is a left inverse of , and that is ...
, which can be seen from the identity (a+bi) \left(\frac - \frac i\right) = \frac=1. It follows that the Gaussian rationals form a number field which is two-dimensional as a vector space over * More generally, for any
square-free {{no footnotes, date=December 2015 In mathematics, a square-free element is an element ''r'' of a unique factorization domain ''R'' that is not divisible by a non-trivial square. This means that every ''s'' such that s^2\mid r is a unit of ''R''. A ...
integer the
quadratic field In algebraic number theory, a quadratic field is an algebraic number field of degree two over \mathbf, the rational numbers. Every such quadratic field is some \mathbf(\sqrt) where d is a (uniquely defined) square-free integer different from 0 a ...
\mathbb (\sqrt) is a number field obtained by adjoining the square root of d to the field of rational numbers. Arithmetic operations in this field are defined in analogy with the case of Gaussian rational numbers, * The cyclotomic field \mathbb(\zeta_n),where \zeta_n = \exp is a number field obtained from \mathbb by adjoining a primitive nth root of unity \zeta_n. This field contains all complex ''n''th roots of unity and its dimension over \mathbb is equal to \varphi(n), where \varphi is the
Euler totient function In number theory, Euler's totient function counts the positive integers up to a given integer that are relatively prime to . It is written using the Greek letter phi as \varphi(n) or \phi(n), and may also be called Euler's phi function. In ot ...
. Non-Examples * The
real number In mathematics, a real number is a number that can be used to measure a ''continuous'' one-dimensional quantity such as a distance, duration or temperature. Here, ''continuous'' means that values can have arbitrarily small variations. Every real ...
s, and the
complex number In mathematics, a complex number is an element of a number system that extends the real numbers with a specific element denoted , called the imaginary unit and satisfying the equation i^= -1; every complex number can be expressed in the form ...
s, are fields which have infinite dimension as \mathbb-vector spaces, hence, they are ''not'' number fields. This follows from the uncountability of \mathbb and \mathbb as sets, whereas every number field is necessarily
countable In mathematics, a set is countable if either it is finite or it can be made in one to one correspondence with the set of natural numbers. Equivalently, a set is ''countable'' if there exists an injective function from it into the natural numbers ...
. * The set \mathbb^2 of
ordered pair In mathematics, an ordered pair (''a'', ''b'') is a pair of objects. The order in which the objects appear in the pair is significant: the ordered pair (''a'', ''b'') is different from the ordered pair (''b'', ''a'') unless ''a'' = ''b''. (In con ...
s of rational numbers, with the entry-wise addition and multiplication is a two-dimensional commutative algebra over However, it is not a field, since it has
zero divisor In abstract algebra, an element of a ring is called a left zero divisor if there exists a nonzero in such that , or equivalently if the map from to that sends to is not injective. Similarly, an element of a ring is called a right zero ...
s: (1, 0) \cdot (0, 1) = (1 \cdot 0, 0 \cdot 1) = (0,0)


Algebraicity, and ring of integers

Generally, in
abstract algebra In mathematics, more specifically algebra, abstract algebra or modern algebra is the study of algebraic structures. Algebraic structures include groups, rings, fields, modules, vector spaces, lattices, and algebras over a field. The term ''a ...
, a field extension K / L is algebraic if every element f of the bigger field K is the zero of a
polynomial In mathematics, a polynomial is an expression consisting of indeterminates (also called variables) and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An exa ...
with coefficients e_0,\ldots,e_m in :p(f) = e_mf^m + e_f^ + \cdots + e_1f + e_0 = 0 Every field extension of finite degree is algebraic. (Proof: for x in simply consider 1,x,x^2,x^3,\ldots – we get a linear dependence, i.e. a polynomial that x is a root of.) In particular this applies to algebraic number fields, so any element f of an algebraic number field K can be written as a zero of a polynomial with rational coefficients. Therefore, elements of K are also referred to as ''
algebraic numbers An algebraic number is a number that is a root of a non-zero polynomial in one variable with integer (or, equivalently, rational) coefficients. For example, the golden ratio, (1 + \sqrt)/2, is an algebraic number, because it is a root of the po ...
''. Given a polynomial p such that p(f)=0, it can be arranged such that the leading coefficient e_m is one, by dividing all coefficients by it, if necessary. A polynomial with this property is known as a
monic polynomial In algebra, a monic polynomial is a single-variable polynomial (that is, a univariate polynomial) in which the leading coefficient (the nonzero coefficient of highest degree) is equal to 1. Therefore, a monic polynomial has the form: :x^n+c_x^+\cd ...
. In general it will have rational coefficients. If, however, its coefficients are actually all integers, f is called an ''
algebraic integer In algebraic number theory, an algebraic integer is a complex number which is integral over the integers. That is, an algebraic integer is a complex root of some monic polynomial (a polynomial whose leading coefficient is 1) whose coefficients ...
''. Any (usual) integer z \in \mathbb is an algebraic integer, as it is the zero of the linear monic polynomial: :p(t) = t - z. It can be shown that any algebraic integer that is also a rational number must actually be an integer, hence the name "algebraic integer". Again using abstract algebra, specifically the notion of a
finitely generated module In mathematics, a finitely generated module is a module that has a finite generating set. A finitely generated module over a ring ''R'' may also be called a finite ''R''-module, finite over ''R'', or a module of finite type. Related concepts in ...
, it can be shown that the sum and the product of any two algebraic integers is still an algebraic integer. It follows that the algebraic integers in K form a
ring Ring may refer to: * Ring (jewellery), a round band, usually made of metal, worn as ornamental jewelry * To make a sound with a bell, and the sound made by a bell :(hence) to initiate a telephone connection Arts, entertainment and media Film and ...
denoted \mathcal_K called the
ring of integers In mathematics, the ring of integers of an algebraic number field K is the ring of all algebraic integers contained in K. An algebraic integer is a root of a monic polynomial with integer coefficients: x^n+c_x^+\cdots+c_0. This ring is often deno ...
of It is a subring of (that is, a ring contained in) A field contains no
zero divisors In abstract algebra, an element of a ring is called a left zero divisor if there exists a nonzero in such that , or equivalently if the map from to that sends to is not injective. Similarly, an element of a ring is called a right zero ...
and this property is inherited by any subring, so the ring of integers of K is an
integral domain In mathematics, specifically abstract algebra, an integral domain is a nonzero commutative ring in which the product of any two nonzero elements is nonzero. Integral domains are generalizations of the ring of integers and provide a natural set ...
. The field K is the
field of fractions In abstract algebra, the field of fractions of an integral domain is the smallest field in which it can be embedded. The construction of the field of fractions is modeled on the relationship between the integral domain of integers and the field ...
of the integral domain This way one can get back and forth between the algebraic number field K and its ring of integers Rings of algebraic integers have three distinctive properties: firstly, \mathcal_K is an integral domain that is integrally closed in its field of fractions Secondly, \mathcal_K is a
Noetherian ring In mathematics, a Noetherian ring is a ring that satisfies the ascending chain condition on left and right ideals; if the chain condition is satisfied only for left ideals or for right ideals, then the ring is said left-Noetherian or right-Noether ...
. Finally, every nonzero
prime ideal In algebra, a prime ideal is a subset of a ring that shares many important properties of a prime number in the ring of integers. The prime ideals for the integers are the sets that contain all the multiples of a given prime number, together with ...
of \mathcal_K is maximal or, equivalently, the
Krull dimension In commutative algebra, the Krull dimension of a commutative ring ''R'', named after Wolfgang Krull, is the supremum of the lengths of all chains of prime ideals. The Krull dimension need not be finite even for a Noetherian ring. More generally t ...
of this ring is one. An abstract commutative ring with these three properties is called a ''
Dedekind ring In abstract algebra, a Dedekind domain or Dedekind ring, named after Richard Dedekind, is an integral domain in which every nonzero proper ideal factors into a product of prime ideals. It can be shown that such a factorization is then necessarily ...
'' (or ''Dedekind domain''), in honor of Richard Dedekind, who undertook a deep study of rings of algebraic integers.


Unique factorization

For general
Dedekind ring In abstract algebra, a Dedekind domain or Dedekind ring, named after Richard Dedekind, is an integral domain in which every nonzero proper ideal factors into a product of prime ideals. It can be shown that such a factorization is then necessarily ...
s, in particular rings of integers, there is a unique factorization of ideals into a product of
prime ideal In algebra, a prime ideal is a subset of a ring that shares many important properties of a prime number in the ring of integers. The prime ideals for the integers are the sets that contain all the multiples of a given prime number, together with ...
s. For example, the ideal (6) in the ring \mathbf
sqrt In mathematics, a square root of a number is a number such that ; in other words, a number whose ''square'' (the result of multiplying the number by itself, or  ⋅ ) is . For example, 4 and −4 are square roots of 16, because . ...
/math> of
quadratic integers In number theory, quadratic integers are a generalization of the usual integers to quadratic fields. Quadratic integers are algebraic integers of degree two, that is, solutions of equations of the form : with and (usual) integers. When algebra ...
factors into prime ideals as : (6) = (2, 1 + \sqrt)(2,1 - \sqrt)(3, 1 + \sqrt)(3, 1 - \sqrt) However, unlike \mathbf as the ring of integers of the ring of integers of a proper extension of \mathbf need not admit
unique factorization In mathematics, a unique factorization domain (UFD) (also sometimes called a factorial ring following the terminology of Bourbaki) is a ring in which a statement analogous to the fundamental theorem of arithmetic holds. Specifically, a UFD is a ...
of numbers into a product of prime numbers or, more precisely,
prime element In mathematics, specifically in abstract algebra, a prime element of a commutative ring is an object satisfying certain properties similar to the prime numbers in the integers and to irreducible polynomials. Care should be taken to distinguish pri ...
s. This happens already for
quadratic integer In number theory, quadratic integers are a generalization of the usual integers to quadratic fields. Quadratic integers are algebraic integers of degree two, that is, solutions of equations of the form : with and (usual) integers. When algebra ...
s, for example in the uniqueness of the factorization fails: : 6 = 2 \cdot 3 = (1 + \sqrt) \cdot (1 - \sqrt) Using the
norm Naturally occurring radioactive materials (NORM) and technologically enhanced naturally occurring radioactive materials (TENORM) consist of materials, usually industrial wastes or by-products enriched with radioactive elements found in the envi ...
it can be shown that these two factorization are actually inequivalent in the sense that the factors do not just differ by a
unit Unit may refer to: Arts and entertainment * UNIT, a fictional military organization in the science fiction television series ''Doctor Who'' * Unit of action, a discrete piece of action (or beat) in a theatrical presentation Music * ''Unit'' (alb ...
in Euclidean domains are unique factorization domains; for example the ring of
Gaussian integer In number theory, a Gaussian integer is a complex number whose real and imaginary parts are both integers. The Gaussian integers, with ordinary addition and multiplication of complex numbers, form an integral domain, usually written as \mathbf /ma ...
s, and the ring of Eisenstein integers, where \omega is a cube root of unity (unequal to 1), have this property.


Analytic objects: ζ-functions, ''L''-functions, and class number formula

The failure of unique factorization is measured by the class number, commonly denoted ''h'', the cardinality of the so-called
ideal class group In number theory, the ideal class group (or class group) of an algebraic number field is the quotient group where is the group of fractional ideals of the ring of integers of , and is its subgroup of principal ideals. The class group is a mea ...
. This group is always finite. The ring of integers \mathcal_K possesses unique factorization if and only if it is a principal ring or, equivalently, if K has class number 1. Given a number field, the class number is often difficult to compute. The
class number problem In mathematics, the Gauss class number problem (for imaginary quadratic fields), as usually understood, is to provide for each ''n'' ≥ 1 a complete list of imaginary quadratic fields \mathbb(\sqrt) (for negative integers ''d'') having c ...
, going back to
Gauss Johann Carl Friedrich Gauss (; german: Gauß ; la, Carolus Fridericus Gauss; 30 April 177723 February 1855) was a German mathematician and physicist who made significant contributions to many fields in mathematics and science. Sometimes refer ...
, is concerned with the existence of imaginary quadratic number fields (i.e., \mathbf \sqrt, d \ge 1) with prescribed class number. The
class number formula In number theory, the class number formula relates many important invariants of a number field to a special value of its Dedekind zeta function. General statement of the class number formula We start with the following data: * is a number field. ...
relates ''h'' to other fundamental invariants of It involves the
Dedekind zeta function In mathematics, the Dedekind zeta function of an algebraic number field ''K'', generally denoted ζ''K''(''s''), is a generalization of the Riemann zeta function (which is obtained in the case where ''K'' is the field of rational numbers Q). It ca ...
ζK(s), a function in a complex variable ''s'', defined by :\zeta_F(s) := \prod_ \frac . (The product is over all prime ideals of N(\mathfrak p) denotes the norm of the prime ideal or, equivalently, the (finite) number of elements in the
residue field In mathematics, the residue field is a basic construction in commutative algebra. If ''R'' is a commutative ring and ''m'' is a maximal ideal, then the residue field is the quotient ring ''k'' = ''R''/''m'', which is a field. Frequently, ''R'' is a ...
The infinite product converges only for Re(''s'') > 1, in general
analytic continuation In complex analysis, a branch of mathematics, analytic continuation is a technique to extend the domain of definition of a given analytic function. Analytic continuation often succeeds in defining further values of a function, for example in a n ...
and the
functional equation In mathematics, a functional equation is, in the broadest meaning, an equation in which one or several functions appear as unknowns. So, differential equations and integral equations are functional equations. However, a more restricted meaning ...
for the zeta-function are needed to define the function for all ''s''). The Dedekind zeta-function generalizes the
Riemann zeta-function The Riemann zeta function or Euler–Riemann zeta function, denoted by the Greek letter (zeta), is a mathematical function of a complex variable defined as \zeta(s) = \sum_^\infty \frac = \frac + \frac + \frac + \cdots for \operatorname(s) > ...
in that ζ\mathbb(''s'') = ζ(''s''). The class number formula states that ζK(''s'') has a
simple pole In complex analysis (a branch of mathematics), a pole is a certain type of singularity (mathematics), singularity of a complex-valued function of a complex number, complex variable. In some sense, it is the simplest type of singularity. Technical ...
at ''s'' = 1 and at this point the
residue Residue may refer to: Chemistry and biology * An amino acid, within a peptide chain * Crop residue, materials left after agricultural processes * Pesticide residue, refers to the pesticides that may remain on or in food after they are applied ...
is given by : \frac. Here ''r''1 and ''r''2 classically denote the number of real embeddings and pairs of complex embeddings of respectively. Moreover, Reg is the regulator of ''w'' the number of
roots of unity In mathematics, a root of unity, occasionally called a de Moivre number, is any complex number that yields 1 when raised to some positive integer power . Roots of unity are used in many branches of mathematics, and are especially important in ...
in K and ''D'' is the discriminant of
Dirichlet L-function In mathematics, a Dirichlet ''L''-series is a function of the form :L(s,\chi) = \sum_^\infty \frac. where \chi is a Dirichlet character and ''s'' a complex variable with real part greater than 1. It is a special case of a Dirichlet series. By ...
s L(\chi,s) are a more refined variant of \zeta(s). Both types of functions encode the arithmetic behavior of \mathbb and K, respectively. For example, Dirichlet's theorem asserts that in any
arithmetic progression An arithmetic progression or arithmetic sequence () is a sequence of numbers such that the difference between the consecutive terms is constant. For instance, the sequence 5, 7, 9, 11, 13, 15, . . . is an arithmetic progression with a common differ ...
:a, a+m, a+2m,\ldots with
coprime In mathematics, two integers and are coprime, relatively prime or mutually prime if the only positive integer that is a divisor of both of them is 1. Consequently, any prime number that divides does not divide , and vice versa. This is equivale ...
a and m, there are infinitely many prime numbers. This theorem is implied by the fact that the Dirichlet L-function is nonzero at s=1. Using much more advanced techniques including
algebraic K-theory Algebraic ''K''-theory is a subject area in mathematics with connections to geometry, topology, ring theory, and number theory. Geometric, algebraic, and arithmetic objects are assigned objects called ''K''-groups. These are groups in the sense ...
and Tamagawa measures, modern number theory deals with a description, if largely conjectural (see Tamagawa number conjecture), of values of more general
L-function In mathematics, an ''L''-function is a meromorphic function on the complex plane, associated to one out of several categories of mathematical objects. An ''L''-series is a Dirichlet series, usually convergent on a half-plane, that may give ri ...
s.


Bases for number fields


Integral basis

An ''
integral basis In mathematics, a free abelian group is an abelian group with a basis. Being an abelian group means that it is a set with an addition operation that is associative, commutative, and invertible. A basis, also called an integral basis, is a subs ...
'' for a number field K of degree n is a set :''B'' = of ''n'' algebraic integers in K such that every element of the ring of integers \mathcal_K of K can be written uniquely as a Z-linear combination of elements of ''B''; that is, for any ''x'' in \mathcal_K we have :''x'' = ''m''1''b''1 + ⋯ + ''mnbn'', where the ''mi'' are (ordinary) integers. It is then also the case that any element of K can be written uniquely as :''m''1''b''1 + ⋯ + ''mnbn'', where now the ''mi'' are rational numbers. The algebraic integers of K are then precisely those elements of K where the ''mi'' are all integers. Working
locally In mathematics, a mathematical object is said to satisfy a property locally, if the property is satisfied on some limited, immediate portions of the object (e.g., on some ''sufficiently small'' or ''arbitrarily small'' neighborhoods of points). P ...
and using tools such as the
Frobenius map In commutative algebra and field theory, the Frobenius endomorphism (after Ferdinand Georg Frobenius) is a special endomorphism of commutative rings with prime characteristic , an important class which includes finite fields. The endomorphism m ...
, it is always possible to explicitly compute such a basis, and it is now standard for
computer algebra system A computer algebra system (CAS) or symbolic algebra system (SAS) is any mathematical software with the ability to manipulate mathematical expressions in a way similar to the traditional manual computations of mathematicians and scientists. The de ...
s to have built-in programs to do this.


Power basis

Let K be a number field of degree Among all possible bases of K (seen as a \mathbb-vector space), there are particular ones known as power bases, that are bases of the form :B_x = \ for some element By the
primitive element theorem In field theory, the primitive element theorem is a result characterizing the finite degree field extensions that can be generated by a single element. Such a generating element is called a primitive element of the field extension, and the exten ...
, there exists such an x, called a primitive element. If x can be chosen in \mathcal_K and such that B_x is a basis of \mathcal_K as a free Z-module, then B_x is called a
power integral basis In mathematics, a monogenic field is an algebraic number field ''K'' for which there exists an element ''a'' such that the ring of integers ''O'K'' is the subring Z 'a''of ''K'' generated by ''a''. Then ''O'K'' is a quotient of the polynomi ...
, and the field K is called a
monogenic field In mathematics, a monogenic field is an algebraic number field ''K'' for which there exists an element ''a'' such that the ring of integers ''O'K'' is the subring Z 'a''of ''K'' generated by ''a''. Then ''O'K'' is a quotient of the polynomial ...
. An example of a number field that is not monogenic was first given by Dedekind. His example is the field obtained by adjoining a root of the polynomial x^3 - x^2 - 2x - 8 .


Regular representation, trace and discriminant

Recall that any field extension K/\mathbb has a unique \mathbb-vector space structure. Using the multiplication in K, an element x of the field K over the base field \mathbb may be represented by n\times n
matrices Matrix most commonly refers to: * ''The Matrix'' (franchise), an American media franchise ** ''The Matrix'', a 1999 science-fiction action film ** "The Matrix", a fictional setting, a virtual reality environment, within ''The Matrix'' (franchis ...
A = A(x) = (a_)_ by requiring x e_i = \sum_^n a_ e_j, \quad a_\in\Q. Here e_1,\ldots,e_n is a fixed basis for K, viewed as a \mathbb-vector space. The rational numbers a_ are uniquely determined by x and the choice of a basis since any element of K can be uniquely represented as a linear combination of the basis elements. This way of associating a matrix to any element of the field K is called the ''
regular representation In mathematics, and in particular the theory of group representations, the regular representation of a group ''G'' is the linear representation afforded by the group action of ''G'' on itself by translation. One distinguishes the left regular rep ...
''. The square matrix A represents the effect of multiplication by x in the given basis. It follows that if the element y of K is represented by a matrix B, then the product xy is represented by the
matrix product In mathematics, particularly in linear algebra, matrix multiplication is a binary operation that produces a matrix from two matrices. For matrix multiplication, the number of columns in the first matrix must be equal to the number of rows in the s ...
BA.
Invariant Invariant and invariance may refer to: Computer science * Invariant (computer science), an expression whose value doesn't change during program execution ** Loop invariant, a property of a program loop that is true before (and after) each iteratio ...
s of matrices, such as the
trace Trace may refer to: Arts and entertainment Music * ''Trace'' (Son Volt album), 1995 * ''Trace'' (Died Pretty album), 1993 * Trace (band), a Dutch progressive rock band * ''The Trace'' (album) Other uses in arts and entertainment * ''Trace'' ...
,
determinant In mathematics, the determinant is a scalar value that is a function of the entries of a square matrix. It characterizes some properties of the matrix and the linear map represented by the matrix. In particular, the determinant is nonzero if and ...
, and
characteristic polynomial In linear algebra, the characteristic polynomial of a square matrix is a polynomial which is invariant under matrix similarity and has the eigenvalues as roots. It has the determinant and the trace of the matrix among its coefficients. The chara ...
, depend solely on the field element x and not on the basis. In particular, the trace of the matrix A(x) is called the ''
trace Trace may refer to: Arts and entertainment Music * ''Trace'' (Son Volt album), 1995 * ''Trace'' (Died Pretty album), 1993 * Trace (band), a Dutch progressive rock band * ''The Trace'' (album) Other uses in arts and entertainment * ''Trace'' ...
'' of the field element x and denoted \text(x), and the determinant is called the ''
norm Naturally occurring radioactive materials (NORM) and technologically enhanced naturally occurring radioactive materials (TENORM) consist of materials, usually industrial wastes or by-products enriched with radioactive elements found in the envi ...
'' of ''x'' and denoted N(x). Now this can be generalized slightly by instead considering a field extension K/L and giving an L-basis for K. Then, there is an associated matrix A_(x) which has trace \text_(x) and norm \text_(x) defined as the trace and determinant of the matrix A_(x).


Example

Consider the field extension \mathbb(\theta) where \theta = \zeta_3\sqrt /math>. Then, we have a \mathbb-basis given by \ since any x \in \mathbb(\theta) can be expressed as some \mathbb-linear combination a + b\zeta_3\sqrt + c\zeta_3\sqrt = a + b\theta + c\theta^2 Then, we can take some y \in \mathbb(\theta) where y = y_0 + y_1\theta + y_2 \theta^2 and compute x \cdot y. Writing this out gives \begin a(y_0 + y_1\theta + y_2\theta^2) + \\ b(2y_2 + y_0\theta + y_1\theta^2) + \\ c(2y_1 + 2y_2\theta + y_0 \theta^2) \end We can find the matrix A(x) by writing out the associated matrix equation giving \begin a_ & a_ & a_ \\ a_ & a_ & a_ \\ a_ & a_ & a_ \end \begin y_0 \\ y_1 \\ y_2 \end = \begin ay_0 + 2cy_1 + 2by_2 \\ by_0 + ay_1 + 2cy_2 \\ cy_0 + by_1 + ay_2 \end showing A(x) = \begin a & 2c & 2b \\ b & a & 2c \\ c & b & a \end We can then compute the trace and determinant with relative ease, giving the trace and norm.


Properties

By definition, standard properties of traces and determinants of matrices carry over to Tr and N: Tr(''x'') is a
linear function In mathematics, the term linear function refers to two distinct but related notions: * In calculus and related areas, a linear function is a function whose graph is a straight line, that is, a polynomial function of degree zero or one. For dist ...
of ''x'', as expressed by , , and the norm is a multiplicative
homogeneous function In mathematics, a homogeneous function is a function of several variables such that, if all its arguments are multiplied by a scalar, then its value is multiplied by some power of this scalar, called the degree of homogeneity, or simply the ''deg ...
of degree ''n'': , . Here ''λ'' is a rational number, and ''x'', ''y'' are any two elements of The ''
trace form In mathematics, the field trace is a particular function defined with respect to a finite field extension ''L''/''K'', which is a ''K''-linear map from ''L'' onto ''K''. Definition Let ''K'' be a field and ''L'' a finite extension (and hence an ...
'' derived is a
bilinear form In mathematics, a bilinear form is a bilinear map on a vector space (the elements of which are called '' vectors'') over a field ''K'' (the elements of which are called ''scalars''). In other words, a bilinear form is a function that is linear i ...
defined by means of the trace, as Tr_: K \otimes_L K \to L by Tr_(x\otimes y) = Tr_(x\cdot y)\text_(x). The ''integral trace form'', an integer-valued
symmetric matrix In linear algebra, a symmetric matrix is a square matrix that is equal to its transpose. Formally, Because equal matrices have equal dimensions, only square matrices can be symmetric. The entries of a symmetric matrix are symmetric with re ...
is defined as t_ = \text_(b_ib_j), where ''b''1, ..., ''b''n is an integral basis for The ''discriminant'' of K is defined as det(''t''). It is an integer, and is an invariant property of the field K, not depending on the choice of integral basis. The matrix associated to an element ''x'' of K can also be used to give other, equivalent descriptions of algebraic integers. An element ''x'' of K is an algebraic integer if and only if the characteristic polynomial ''p''''A'' of the matrix ''A'' associated to ''x'' is a monic polynomial with integer coefficients. Suppose that the matrix ''A'' that represents an element ''x'' has integer entries in some basis ''e''. By the
Cayley–Hamilton theorem In linear algebra, the Cayley–Hamilton theorem (named after the mathematicians Arthur Cayley and William Rowan Hamilton) states that every square matrix over a commutative ring (such as the real or complex numbers or the integers) satisfies ...
, ''p''''A''(''A'') = 0, and it follows that ''p''''A''(''x'') = 0, so that ''x'' is an algebraic integer. Conversely, if ''x'' is an element of K which is a root of a monic polynomial with integer coefficients then the same property holds for the corresponding matrix ''A''. In this case it can be proven that ''A'' is an
integer matrix In mathematics, an integer matrix is a matrix whose entries are all integers. Examples include binary matrices, the zero matrix, the matrix of ones, the identity matrix, and the adjacency matrices used in graph theory, amongst many others. Integ ...
in a suitable basis of The property of being an algebraic integer is ''defined'' in a way that is independent of a choice of a basis in


Example with integral basis

Consider K = \mathbb(x), where ''x'' satisfies . Then an integral basis is , ''x'', 1/2(''x''2 + 1) and the corresponding integral trace form is \begin 3 & 11 & 61 \\ 11 & 119 & 653 \\ 61 & 653 & 3589 \end. The "3" in the upper left hand corner of this matrix is the trace of the matrix of the map defined by the first basis element (1) in the regular representation of K on This basis element induces the identity map on the 3-dimensional vector space, The trace of the matrix of the identity map on a 3-dimensional vector space is 3. The determinant of this is , the field discriminant; in comparison the root discriminant, or discriminant of the polynomial, is .


Places

Mathematicians of the nineteenth century assumed that algebraic numbers were a type of complex number. This situation changed with the discovery of
p-adic number In mathematics, the -adic number system for any prime number  extends the ordinary arithmetic of the rational numbers in a different way from the extension of the rational number system to the real and complex number systems. The extensi ...
s by Hensel in 1897; and now it is standard to consider all of the various possible embeddings of a number field K into its various topological completions K_ at once. A ''
place Place may refer to: Geography * Place (United States Census Bureau), defined as any concentration of population ** Census-designated place, a populated area lacking its own Municipality, municipal government * "Place", a type of street or road ...
'' of a number field K is an equivalence class of absolute values on Kpg 9. Essentially, an absolute value is a notion to measure the size of elements x of Two such absolute values are considered equivalent if they give rise to the same notion of smallness (or proximity). The equivalence relation between absolute values , \cdot, _0 \sim , \cdot, _1 is given by some \lambda \in \mathbb_ such that, \cdot, _0 = , \cdot, _1^meaning we take the value of the norm , \cdot, _1 to the \lambda-th power. In general, the types of places fall into three regimes. Firstly (and mostly irrelevant), the trivial absolute value , , 0, which takes the value 1 on all non-zero The second and third classes are Archimedean places and non-Archimedean (or ultrametric) places. The completion of K with respect to a place , \cdot, _ is given in both cases by taking
Cauchy sequence In mathematics, a Cauchy sequence (; ), named after Augustin-Louis Cauchy, is a sequence whose elements become arbitrarily close to each other as the sequence progresses. More precisely, given any small positive distance, all but a finite numbe ...
s in Kand dividing out
null sequence As the positive integer n becomes larger and larger, the value n\cdot \sin\left(\tfrac1\right) becomes arbitrarily close to 1. We say that "the limit of the sequence n\cdot \sin\left(\tfrac1\right) equals 1." In mathematics, the limit ...
s, that is, sequences \_ such that , x_n, _\mathfrak \to 0tends to zero when n tends to infinity. This can be shown to be a field again, the so-called completion of K at the given place denoted For the following non-trivial norms occur (
Ostrowski's theorem In number theory, Ostrowski's theorem, due to Alexander Ostrowski (1916), states that every non-trivial absolute value on the rational numbers \Q is equivalent to either the usual real absolute value or a -adic absolute value. Definitions Raisi ...
): the (usual)
absolute value In mathematics, the absolute value or modulus of a real number x, is the non-negative value without regard to its sign. Namely, , x, =x if is a positive number, and , x, =-x if x is negative (in which case negating x makes -x positive), an ...
, sometimes denoted , \cdot, _\infty which gives rise to the complete
topological field In mathematics, a field is a set on which addition, subtraction, multiplication, and division are defined and behave as the corresponding operations on rational and real numbers do. A field is thus a fundamental algebraic structure which is w ...
of the real numbers On the other hand, for any prime number p, the ''p''-adic absolute value is defined by :, ''q'', ''p'' = ''p''−''n'', where ''q'' = ''p''''n'' ''a''/''b'' and ''a'' and ''b'' are integers not divisible by ''p''. It is used to construct the p-adic numbers In contrast to the usual absolute value, the ''p''-adic absolute value gets ''smaller'' when ''q'' is multiplied by ''p'', leading to quite different behavior of \mathbb_p as compared to Note the general situation typically considered is taking a number field K and considering a
prime ideal In algebra, a prime ideal is a subset of a ring that shares many important properties of a prime number in the ring of integers. The prime ideals for the integers are the sets that contain all the multiples of a given prime number, together with ...
\mathfrak \in \text(\mathcal_K) for its associated ring of algebraic numbers Then, there will be a unique place , \cdot, _: K \to \mathbb_ called a non-Archimedean place. In addition, for every embedding \sigma: K \to \mathbb there will be a place called an Archimedean place, denoted This statement is a theorem also called
Ostrowski's theorem In number theory, Ostrowski's theorem, due to Alexander Ostrowski (1916), states that every non-trivial absolute value on the rational numbers \Q is equivalent to either the usual real absolute value or a -adic absolute value. Definitions Raisi ...
.


Examples

The field K = \mathbb (x^6 - 2) = \mathbb(\theta) for \theta = \zeta\sqrt /math> where \zeta is a fixed 6th root of unity, provides a rich example for constructing explicit real and complex Archimedean embeddings, and non-Archimedean embeddings as wellpg 15-16.


Archimedean places

Here we use the standard notation r_1 and r_2 for the number of real and complex embeddings used, respectively (see below). Calculating the archimedean places of a number field K is done as follows: let x be a primitive element of K, with minimal polynomial f (over \mathbb). Over \mathbb, f will generally no longer be irreducible, but its irreducible (real) factors are either of degree one or two. Since there are no repeated roots, there are no repeated factors. The roots r of factors of degree one are necessarily real, and replacing x by r gives an embedding of K into \mathbb; the number of such embeddings is equal to the number of real roots of Restricting the standard absolute value on \mathbb to K gives an archimedean absolute value on K; such an absolute value is also referred to as a ''real place'' of On the other hand, the roots of factors of degree two are pairs of conjugate complex numbers, which allows for two conjugate embeddings into Either one of this pair of embeddings can be used to define an absolute value on K, which is the same for both embeddings since they are conjugate. This absolute value is called a ''complex place'' of If all roots of f above are real (respectively, complex) or, equivalently, any possible embedding K \subseteq \mathbb is actually forced to be inside \mathbb (resp. K is called
totally real In number theory, a number field ''F'' is called totally real if for each embedding of ''F'' into the complex numbers the image lies inside the real numbers. Equivalent conditions are that ''F'' is generated over Q by one root of an integer poly ...
(resp. totally complex).


Non-Archimedean or ultrametric places

To find the non-Archimedean places, let again f and x be as above. In f splits in factors of various degrees, none of which are repeated, and the degrees of which add up to the degree of For each of these p-adically irreducible factors we may suppose that x satisfies f_i and obtain an embedding of K into an algebraic extension of finite degree over Such a
local field In mathematics, a field ''K'' is called a (non-Archimedean) local field if it is complete with respect to a topology induced by a discrete valuation ''v'' and if its residue field ''k'' is finite. Equivalently, a local field is a locally compact ...
behaves in many ways like a number field, and the p-adic numbers may similarly play the role of the rationals; in particular, we can define the norm and trace in exactly the same way, now giving functions mapping to By using this p-adic norm map N_ for the place f_i, we may define an absolute value corresponding to a given p-adically irreducible factor f_i of degree m by, y, _ = , N_(y), _p^Such an absolute value is called an
ultrametric In mathematics, an ultrametric space is a metric space in which the triangle inequality is strengthened to d(x,z)\leq\max\left\. Sometimes the associated metric is also called a non-Archimedean metric or super-metric. Although some of the theorems ...
, non-Archimedean or p-adic place of For any ultrametric place ''v'' we have that , ''x'', ''v'' ≤ 1 for any ''x'' in since the minimal polynomial for ''x'' has integer factors, and hence its ''p''-adic factorization has factors in Z''p''. Consequently, the norm term (constant term) for each factor is a ''p''-adic integer, and one of these is the integer used for defining the absolute value for ''v''.


Prime ideals in ''OK''

For an ultrametric place ''v'', the subset of \mathcal_K defined by , ''x'', ''v'' < 1 is an
ideal Ideal may refer to: Philosophy * Ideal (ethics), values that one actively pursues as goals * Platonic ideal, a philosophical idea of trueness of form, associated with Plato Mathematics * Ideal (ring theory), special subsets of a ring considere ...
\mathfrak of This relies on the ultrametricity of ''v'': given ''x'' and ''y'' in then :, ''x'' + ''y'', ''v'' ≤ max (, ''x'', ''v'', , y, ''v'') < 1. Actually, \mathfrak is even a
prime ideal In algebra, a prime ideal is a subset of a ring that shares many important properties of a prime number in the ring of integers. The prime ideals for the integers are the sets that contain all the multiples of a given prime number, together with ...
. Conversely, given a prime ideal \mathfrak of a
discrete valuation In mathematics, a discrete valuation is an integer valuation on a field ''K''; that is, a function: :\nu:K\to\mathbb Z\cup\ satisfying the conditions: :\nu(x\cdot y)=\nu(x)+\nu(y) :\nu(x+y)\geq\min\big\ :\nu(x)=\infty\iff x=0 for all x,y\in K. ...
can be defined by setting v_\mathfrak(x) = n where ''n'' is the biggest integer such that the ''n''-fold power of the ideal. This valuation can be turned into an ultrametric place. Under this correspondence, (equivalence classes) of ultrametric places of K correspond to prime ideals of For this gives back Ostrowski's theorem: any prime ideal in Z (which is necessarily by a single prime number) corresponds to a non-Archimedean place and vice versa. However, for more general number fields, the situation becomes more involved, as will be explained below. Yet another, equivalent way of describing ultrametric places is by means of localizations of Given an ultrametric place v on a number field the corresponding localization is the subring T of K of all elements x such that ,  ''x'' , ''v'' ≤ 1. By the ultrametric property T is a ring. Moreover, it contains For every element ''x'' of at least one of ''x'' or ''x''−1 is contained in Actually, since ''K''×/''T''× can be shown to be isomorphic to the integers, T is a
discrete valuation ring In abstract algebra, a discrete valuation ring (DVR) is a principal ideal domain (PID) with exactly one non-zero maximal ideal. This means a DVR is an integral domain ''R'' which satisfies any one of the following equivalent conditions: # ''R'' i ...
, in particular a
local ring In abstract algebra, more specifically ring theory, local rings are certain rings that are comparatively simple, and serve to describe what is called "local behaviour", in the sense of functions defined on varieties or manifolds, or of algebraic n ...
. Actually, T is just the localization of \mathcal_K at the prime ideal so Conversely, \mathfrak is the maximal ideal of Altogether, there is a three-way equivalence between ultrametric absolute values, prime ideals, and localizations on a number field.


Lying over theorem and places

Some of the basic theorems in algebraic number theory are the going up and going down theorems, which describe the behavior of some prime ideal \mathfrak \in \text(\mathcal_K) when it is extended as an ideal in \mathcal_L for some field extension We say that an ideal \mathfrak \subset \mathcal_L lies over \mathfrak if Then, one incarnation of the theorem states a prime ideal in \text(\mathcal_L) lies over hence there is always a surjective map\text(\mathcal_L) \to \text(\mathcal_K)induced from the inclusion Since there exists a correspondence between places and prime ideals, this means we can find places dividing a place which is induced from a field extension. That is, if p is a place of then there are places v of L which divide in the sense that their induced prime ideals divide the induced prime ideal of p in In fact, this observation is usefulpg 13 while looking at the base change of an algebraic field extension of \mathbb to one of its completions If we writeK = \fracand write \theta for the induced element of we get a decomposition of Explicitly, this decomposition is\begin K\otimes_\mathbb\mathbb_p &= \frac\otimes_\mathbb\mathbb_p\\ &= \frac \endfurthermore, the induced polynomial Q(X) \in \mathbb_p /math> decomposes asQ(X) = \prod_Q_vbecause of
Hensel's lemma In mathematics, Hensel's lemma, also known as Hensel's lifting lemma, named after Kurt Hensel, is a result in modular arithmetic, stating that if a univariate polynomial has a simple root modulo a prime number , then this root can be ''lifted'' to ...
pg 129-131, hence\begin K\otimes_\mathbb\mathbb_p &\cong \frac \\&\cong \bigoplus_K_v \endMoreover, there are embeddings\begin i_v:&K \to K_v \\ & \theta \mapsto \theta_v \endwhere \theta_v is a root of Q_v giving K_v = \mathbb_p(\theta_v), hence we could writeK_v = i_v(K)\mathbb_p as subsets of \mathbb_p (which is the completion of the algebraic closure of


Ramification

Ramification, generally speaking, describes a geometric phenomenon that can occur with finite-to-one maps (that is, maps f:X\to Y such that the preimages of all points ''y'' in ''Y'' consist only of finitely many points): the cardinality of the
fibers Fiber or fibre (from la, fibra, links=no) is a natural or artificial substance that is significantly longer than it is wide. Fibers are often used in the manufacture of other materials. The strongest engineering materials often incorporate ...
''f''−1(''y'') will generally have the same number of points, but it occurs that, in special points ''y'', this number drops. For example, the map :\Complex \to \Complex , z \mapsto z^n has ''n'' points in each fiber over ''t'', namely the ''n'' (complex) roots of ''t'', except in t = ''0'', where the fiber consists of only one element, ''z'' = 0. One says that the map is "ramified" in zero. This is an example of a
branched covering In mathematics, a branched covering is a map that is almost a covering map, except on a small set. In topology In topology, a map is a ''branched covering'' if it is a covering map everywhere except for a nowhere dense set known as the branch set. ...
of
Riemann surface In mathematics, particularly in complex analysis, a Riemann surface is a connected one-dimensional complex manifold. These surfaces were first studied by and are named after Bernhard Riemann. Riemann surfaces can be thought of as deformed vers ...
s. This intuition also serves to define ramification in algebraic number theory. Given a (necessarily finite) extension of number fields K/L, a prime ideal ''p'' of \mathcal_L generates the ideal ''pO''''K'' of This ideal may or may not be a prime ideal, but, according to the Lasker–Noether theorem (see above), always is given by :''pO''K = ''q''1''e''1 ''q''2''e''2 ⋯ ''q''''m''''e''''m'' with uniquely determined prime ideals ''q''''i'' of \mathcal_K and numbers (called ramification indices) ''e''''i''. Whenever one ramification index is bigger than one, the prime ''p'' is said to ramify in The connection between this definition and the geometric situation is delivered by the map of spectra of rings In fact,
unramified morphism In algebraic geometry, an unramified morphism is a morphism f: X \to Y of schemes such that (a) it is locally of finite presentation and (b) for each x \in X and y = f(x), we have that # The residue field k(x) is a separable algebraic extension of ...
s of
scheme A scheme is a systematic plan for the implementation of a certain idea. Scheme or schemer may refer to: Arts and entertainment * ''The Scheme'' (TV series), a BBC Scotland documentary series * The Scheme (band), an English pop band * ''The Schem ...
s in
algebraic geometry Algebraic geometry is a branch of mathematics, classically studying zeros of multivariate polynomials. Modern algebraic geometry is based on the use of abstract algebraic techniques, mainly from commutative algebra, for solving geometrical ...
are a direct generalization of unramified extensions of number fields. Ramification is a purely local property, i.e., depends only on the completions around the primes ''p'' and ''q''''i''. The
inertia group In number theory, more specifically in local class field theory, the ramification groups are a filtration of the Galois group of a local field extension, which gives detailed information on the ramification phenomena of the extension. Ramificat ...
measures the difference between the local Galois groups at some place and the Galois groups of the involved finite residue fields.


An example

The following example illustrates the notions introduced above. In order to compute the ramification index of where :''f''(''x'') = ''x''3 − ''x'' − 1 = 0, at 23, it suffices to consider the field extension Up to 529 = 232 (i.e., modulo 529) ''f'' can be factored as :''f''(''x'') = (''x'' + 181)(''x''2 − 181''x'' − 38) = ''gh''. Substituting in the first factor ''g'' modulo 529 yields ''y'' + 191, so the valuation ,  ''y'' , ''g'' for ''y'' given by ''g'' is ,  −191 , 23 = 1. On the other hand, the same substitution in ''h'' yields Since 161 = 7 × 23, :\left\vert y \right\vert_h = \sqrt_ = \frac Since possible values for the absolute value of the place defined by the factor ''h'' are not confined to integer powers of 23, but instead are integer powers of the square root of 23, the ramification index of the field extension at 23 is two. The valuations of any element of K can be computed in this way using
resultant In mathematics, the resultant of two polynomials is a polynomial expression of their coefficients, which is equal to zero if and only if the polynomials have a common root (possibly in a field extension), or, equivalently, a common factor (ove ...
s. If, for example ''y'' = ''x''2 − ''x'' − 1, using the resultant to eliminate ''x'' between this relationship and ''f'' = ''x''3 − ''x'' − 1 = 0 gives . If instead we eliminate with respect to the factors ''g'' and ''h'' of ''f'', we obtain the corresponding factors for the polynomial for ''y'', and then the 23-adic valuation applied to the constant (norm) term allows us to compute the valuations of ''y'' for ''g'' and ''h'' (which are both 1 in this instance.)


Dedekind discriminant theorem

Much of the significance of the discriminant lies in the fact that ramified ultrametric places are all places obtained from factorizations in \mathbb_p where ''p'' divides the discriminant. This is even true of the polynomial discriminant; however the converse is also true, that if a prime ''p'' divides the discriminant, then there is a ''p''-place which ramifies. For this converse the field discriminant is needed. This is the Dedekind discriminant theorem. In the example above, the discriminant of the number field \mathbb(x) with ''x''3 − ''x'' − 1 = 0 is −23, and as we have seen the 23-adic place ramifies. The Dedekind discriminant tells us it is the only ultrametric place which does. The other ramified place comes from the absolute value on the complex embedding of K.


Galois groups and Galois cohomology

Generally in abstract algebra, field extensions ''K'' / ''L'' can be studied by examining the
Galois group In mathematics, in the area of abstract algebra known as Galois theory, the Galois group of a certain type of field extension is a specific group associated with the field extension. The study of field extensions and their relationship to the pol ...
Gal(''K'' / ''L''), consisting of field automorphisms of K leaving L elementwise fixed. As an example, the Galois group \mathrm(\mathbb(\zeta_n) / \mathbb) of the cyclotomic field extension of degree ''n'' (see above) is given by (Z/''n''Z)×, the group of invertible elements in Z/''n''Z. This is the first stepstone into
Iwasawa theory In number theory, Iwasawa theory is the study of objects of arithmetic interest over infinite towers of number fields. It began as a Galois module theory of ideal class groups, initiated by (), as part of the theory of cyclotomic fields. In th ...
. In order to include all possible extensions having certain properties, the Galois group concept is commonly applied to the (infinite) field extension / ''K'' of the
algebraic closure In mathematics, particularly abstract algebra, an algebraic closure of a field ''K'' is an algebraic extension of ''K'' that is algebraically closed. It is one of many closures in mathematics. Using Zorn's lemmaMcCarthy (1991) p.21Kaplansky ( ...
, leading to the
absolute Galois group In mathematics, the absolute Galois group ''GK'' of a field ''K'' is the Galois group of ''K''sep over ''K'', where ''K''sep is a separable closure of ''K''. Alternatively it is the group of all automorphisms of the algebraic closure of ''K'' t ...
''G'' := Gal( / ''K'') or just Gal(''K''), and to the extension K / \mathbb. The
fundamental theorem of Galois theory In mathematics, the fundamental theorem of Galois theory is a result that describes the structure of certain types of field extensions in relation to groups. It was proved by Évariste Galois in his development of Galois theory. In its most basi ...
links fields in between K and its algebraic closure and closed subgroups of Gal(''K''). For example, the
abelianization In mathematics, more specifically in abstract algebra, the commutator subgroup or derived subgroup of a group is the subgroup generated by all the commutators of the group. The commutator subgroup is important because it is the smallest normal ...
(the biggest abelian quotient) ''G''ab of ''G'' corresponds to a field referred to as the maximal
abelian extension In abstract algebra, an abelian extension is a Galois extension whose Galois group is abelian. When the Galois group is also cyclic, the extension is also called a cyclic extension. Going in the other direction, a Galois extension is called solvable ...
''K''ab (called so since any further extension is not abelian, i.e., does not have an abelian Galois group). By the
Kronecker–Weber theorem In algebraic number theory, it can be shown that every cyclotomic field is an abelian extension of the rational number field Q, having Galois group of the form (\mathbb Z/n\mathbb Z)^\times. The Kronecker–Weber theorem provides a partial conve ...
, the maximal abelian extension of \mathbb is the extension generated by all
roots of unity In mathematics, a root of unity, occasionally called a de Moivre number, is any complex number that yields 1 when raised to some positive integer power . Roots of unity are used in many branches of mathematics, and are especially important in ...
. For more general number fields,
class field theory In mathematics, class field theory (CFT) is the fundamental branch of algebraic number theory whose goal is to describe all the abelian Galois extensions of local and global fields using objects associated to the ground field. Hilbert is credit ...
, specifically the
Artin reciprocity law The Artin reciprocity law, which was established by Emil Artin in a series of papers (1924; 1927; 1930), is a general theorem in number theory that forms a central part of global class field theory. The term "reciprocity law" refers to a long line ...
gives an answer by describing ''G''ab in terms of the
idele class group In abstract algebra, an adelic algebraic group is a semitopological group defined by an algebraic group ''G'' over a number field ''K'', and the adele ring ''A'' = ''A''(''K'') of ''K''. It consists of the points of ''G'' having values in ''A''; the ...
. Also notable is the
Hilbert class field In algebraic number theory, the Hilbert class field ''E'' of a number field ''K'' is the Maximal abelian extension, maximal abelian unramified extension of ''K''. Its degree over ''K'' equals the class number of ''K'' and the Galois group of ''E'' ...
, the maximal abelian unramified field extension of K. It can be shown to be finite over K, its Galois group over K is isomorphic to the class group of K, in particular its degree equals the class number ''h'' of K (see above). In certain situations, the Galois group
acts The Acts of the Apostles ( grc-koi, Πράξεις Ἀποστόλων, ''Práxeis Apostólōn''; la, Actūs Apostolōrum) is the fifth book of the New Testament; it tells of the founding of the Christian Church and the spread of its message ...
on other mathematical objects, for example a group. Such a group is then also referred to as a Galois module. This enables the use of group cohomology for the Galois group Gal(''K''), also known as
Galois cohomology In mathematics, Galois cohomology is the study of the group cohomology of Galois modules, that is, the application of homological algebra to modules for Galois groups. A Galois group ''G'' associated to a field extension ''L''/''K'' acts in a nat ...
, which in the first place measures the failure of exactness of taking Gal(''K'')-invariants, but offers deeper insights (and questions) as well. For example, the Galois group ''G'' of a field extension ''L'' / ''K'' acts on ''L''×, the nonzero elements of ''L''. This Galois module plays a significant role in many arithmetic dualities, such as
Poitou-Tate duality In mathematics, Tate duality or Poitou–Tate duality is a duality theorem for Galois cohomology groups of modules over the Galois group of an algebraic number field or local field, introduced by and . Local Tate duality For a ''p''-adic local f ...
. The
Brauer group Brauer or Bräuer is a surname of German origin, meaning "brewer". Notable people with the name include:- * Alfred Brauer (1894–1985), German-American mathematician, brother of Richard * Andreas Brauer (born 1973), German film producer * Arik ...
of originally conceived to classify
division algebra In the field of mathematics called abstract algebra, a division algebra is, roughly speaking, an algebra over a field in which division, except by zero, is always possible. Definitions Formally, we start with a non-zero algebra ''D'' over a fie ...
s over K, can be recast as a cohomology group, namely H2(Gal (''K'', ×).


Local-global principle

Generally speaking, the term "local to global" refers to the idea that a global problem is first done at a local level, which tends to simplify the questions. Then, of course, the information gained in the local analysis has to be put together to get back to some global statement. For example, the notion of sheaves reifies that idea in
topology In mathematics, topology (from the Greek language, Greek words , and ) is concerned with the properties of a mathematical object, geometric object that are preserved under Continuous function, continuous Deformation theory, deformations, such ...
and
geometry Geometry (; ) is, with arithmetic, one of the oldest branches of mathematics. It is concerned with properties of space such as the distance, shape, size, and relative position of figures. A mathematician who works in the field of geometry is c ...
.


Local and global fields

Number fields share a great deal of similarity with another class of fields much used in
algebraic geometry Algebraic geometry is a branch of mathematics, classically studying zeros of multivariate polynomials. Modern algebraic geometry is based on the use of abstract algebraic techniques, mainly from commutative algebra, for solving geometrical ...
known as function fields of
algebraic curve In mathematics, an affine algebraic plane curve is the zero set of a polynomial in two variables. A projective algebraic plane curve is the zero set in a projective plane of a homogeneous polynomial in three variables. An affine algebraic plane c ...
s over
finite field In mathematics, a finite field or Galois field (so-named in honor of Évariste Galois) is a field that contains a finite number of elements. As with any field, a finite field is a set on which the operations of multiplication, addition, subtr ...
s. An example is ''K''''p''(''T''). They are similar in many respects, for example in that number rings are one-dimensional regular rings, as are the
coordinate ring In algebraic geometry, an affine variety, or affine algebraic variety, over an algebraically closed field is the zero-locus in the affine space of some finite family of polynomials of variables with coefficients in that generate a prime idea ...
s (the quotient fields of which is the function field in question) of curves. Therefore, both types of field are called
global field In mathematics, a global field is one of two type of fields (the other one is local field) which are characterized using valuations. There are two kinds of global fields: * Algebraic number field: A finite extension of \mathbb *Global function fi ...
s. In accordance with the philosophy laid out above, they can be studied at a local level first, that is to say, by looking at the corresponding
local field In mathematics, a field ''K'' is called a (non-Archimedean) local field if it is complete with respect to a topology induced by a discrete valuation ''v'' and if its residue field ''k'' is finite. Equivalently, a local field is a locally compact ...
s. For number fields the local fields are the completions of K at all places, including the archimedean ones (see
local analysis In mathematics, the term local analysis has at least two meanings, both derived from the idea of looking at a problem relative to each prime number ''p'' first, and then later trying to integrate the information gained at each prime into a 'global' ...
). For function fields, the local fields are completions of the local rings at all points of the curve for function fields. Many results valid for function fields also hold, at least if reformulated properly, for number fields. However, the study of number fields often poses difficulties and phenomena not encountered in function fields. For example, in function fields, there is no dichotomy into non-archimedean and archimedean places. Nonetheless, function fields often serves as a source of intuition what should be expected in the number field case.


Hasse principle

A prototypical question, posed at a global level, is whether some polynomial equation has a solution in If this is the case, this solution is also a solution in all completions. The
local-global principle In mathematics, Helmut Hasse's local–global principle, also known as the Hasse principle, is the idea that one can find an integer solution to an equation by using the Chinese remainder theorem to piece together solutions modulo powers of each ...
or Hasse principle asserts that for quadratic equations, the converse holds, as well. Thereby, checking whether such an equation has a solution can be done on all the completions of which is often easier, since analytic methods (classical analytic tools such as intermediate value theorem at the archimedean places and
p-adic analysis In mathematics, ''p''-adic analysis is a branch of number theory that deals with the mathematical analysis of functions of ''p''-adic numbers. The theory of complex-valued numerical functions on the ''p''-adic numbers is part of the theory of lo ...
at the nonarchimedean places) can be used. This implication does not hold, however, for more general types of equations. However, the idea of passing from local data to global ones proves fruitful in class field theory, for example, where
local class field theory In mathematics, local class field theory, introduced by Helmut Hasse, is the study of abelian extensions of local fields; here, "local field" means a field which is complete with respect to an absolute value or a discrete valuation with a finite res ...
is used to obtain global insights mentioned above. This is also related to the fact that the Galois groups of the completions ''K''v can be explicitly determined, whereas the Galois groups of global fields, even of \mathbb are far less understood.


Adeles and ideles

In order to assemble local data pertaining to all local fields attached to the
adele ring Adele Laurie Blue Adkins (, ; born 5 May 1988), professionally known by the mononym Adele, is an English singer and songwriter. After graduating in arts from the BRIT School in 2006, Adele signed a reco ...
is set up. A multiplicative variant is referred to as
idele In abstract algebra, an adelic algebraic group is a semitopological group defined by an algebraic group ''G'' over a number field ''K'', and the adele ring ''A'' = ''A''(''K'') of ''K''. It consists of the points of ''G'' having values in ''A''; the ...
s.


See also


Generalizations

*
Algebraic function field In mathematics, an algebraic function field (often abbreviated as function field) of ''n'' variables over a field ''k'' is a finitely generated field extension ''K''/''k'' which has transcendence degree ''n'' over ''k''. Equivalently, an algebrai ...


Algebraic number theory

*
Dirichlet's unit theorem In mathematics, Dirichlet's unit theorem is a basic result in algebraic number theory due to Peter Gustav Lejeune Dirichlet. It determines the rank of the group of units in the ring of algebraic integers of a number field . The regulator is a pos ...
,
S-unit In mathematics, in the field of algebraic number theory, an ''S''-unit generalises the idea of unit of the ring of integers of the field. Many of the results which hold for units are also valid for ''S''-units. Definition Let ''K'' be a number ...
*
Kummer extension In abstract algebra and number theory, Kummer theory provides a description of certain types of field extensions involving the adjunction of ''n''th roots of elements of the base field. The theory was originally developed by Ernst Eduard Kummer a ...
*
Minkowski's theorem In mathematics, Minkowski's theorem is the statement that every convex set in \mathbb^n which is symmetric with respect to the origin and which has volume greater than 2^n contains a non-zero integer point (meaning a point in \Z^n that is not t ...
,
Geometry of numbers Geometry of numbers is the part of number theory which uses geometry for the study of algebraic numbers. Typically, a ring of algebraic integers is viewed as a lattice in \mathbb R^n, and the study of these lattices provides fundamental informatio ...
*
Chebotarev's density theorem Chebotarev's density theorem in algebraic number theory describes statistically the splitting of primes in a given Galois extension ''K'' of the field \mathbb of rational numbers. Generally speaking, a prime integer will factor into several ideal ...


Class field theory

*
Ray class group In mathematics, a ray class field is an abelian extension of a global field associated with a ray class group of ideal classes or idele classes. Every finite abelian extension of a number field is contained in one of its ray class fields. The te ...
* Decomposition group * Genus field


Notes


References

* * Keith Conrad, http://www.math.uconn.edu/~kconrad/blurbs/gradnumthy/unittheorem.pdf * * Helmut Hasse, ''Number Theory'', Springer ''Classics in Mathematics'' Series (2002) * Serge Lang, ''Algebraic Number Theory'', second edition, Springer, 2000 * Richard A. Mollin, ''Algebraic Number Theory'', CRC, 1999 * Ram Murty, ''Problems in Algebraic Number Theory'', Second Edition, Springer, 2005 * * *{{Citation , last1=Neukirch , first1=Jürgen , author1-link=Jürgen Neukirch , last2=Schmidt , first2=Alexander , last3=Wingberg , first3=Kay , title=Cohomology of Number Fields , publisher=
Springer-Verlag Springer Science+Business Media, commonly known as Springer, is a German multinational publishing company of books, e-books and peer-reviewed journals in science, humanities, technical and medical (STM) publishing. Originally founded in 1842 in ...
, location=Berlin, New York , series=Grundlehren der Mathematischen Wissenschaften , isbn=978-3-540-66671-4 , mr=1737196 , year=2000 , volume=323 , zbl=1136.11001 * André Weil, ''Basic Number Theory'', third edition, Springer, 1995 Algebraic number theory Field (mathematics)