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In [[mathematics]], a '''quaternion algebra''' over a field ''F'' is a [[central simple algebra]] ''A'' over ''F''<ref>See Peirce. Associative algebras. Springer. Lemma at page 14.</ref><ref>See Milies & Sehgal, An introduction to group rings, exercise 17, chapter 2.</ref> that has dimension 4 over ''F''. Every quaternion algebra becomes the matrix algebra by ''extending scalars'' (=[[tensor product of algebras|tensoring]] with a field extension), i.e. for a suitable [[field extension]] ''K'' of ''F'', <math>A \otimes_F K</math> is isomorphic to the 2×2 [[matrix algebra]] over ''K''. | |||
The notion of a quaternion algebra can be seen as a generalization of the [[Hamilton quaternions]] to an arbitrary base field. The Hamilton quaternions are a quaternion algebra (in the above sense) over <math>F = \mathbb{R}</math> (the [[real number field]]), and indeed the only one over ℝ apart from the 2×2 real matrix algebra, up to isomorphism. | |||
==Structure== | |||
''Quaternion algebra'' here means something more general than the algebra of [[Hamilton quaternions]]. When the coefficient field ''F'' does not have characteristic 2, every quaternion algebra over ''F'' can be described as a 4-dimensional ''F''-vector space with basis <math>\{ 1, i, j, k\}</math>, with the following multiplication rules: | |||
:<math>i^2=a</math> | |||
:<math>j^2=b</math> | |||
:<math>ij=k</math> | |||
:<math>ji=-k</math> | |||
where ''a'' and ''b'' are any given nonzero elements of ''F''. From these rules we get: | |||
:<math>k^2=ijij=-iijj=-ab</math> | |||
(The Hamilton quaternions are the case where <math>F=\mathbb{R}</math> and ''a'' = ''b'' = −1.) The algebra defined in this way is denoted (''a'',''b'')<sub>''F''</sub> or simply (''a'',''b'').<ref name=GS2>Gille & Szamuely (2006) p.2</ref> When ''F'' has characteristic 2, a different explicit description in terms of a basis of 4 elements is also possible, but in any event the definition of a quaternion algebra over ''F'' as a 4-dimensional central simple algebra over ''F'' applies uniformly in all characteristics. | |||
A quaternion algebra (''a'',''b'')<sub>''F''</sub> is either a [[division algebra]] or isomorphic to the [[matrix algebra]] of 2×2 matrices over ''F'': the latter case is termed ''split''.<ref name=GS3>Gille & Szamuely (2006) p.3</ref> The ''norm form'' | |||
:<math>N(t + xi +yj + zk) = t^2 - ax^2 - by^2 + abz^2 \ </math> | |||
defines a structure of division algebra if and only if the norm is an [[anisotropic quadratic form]], that is, zero only on the zero element. The conic ''C''(''a'',''b'') defined by | |||
:<math>a x^2 + b y^2 = z^2 \ </math> | |||
has a point (''x'',''y'',''z'') with coordinates in ''F'' in the split case.<ref name=GS7>Gille & Szamuely (2006) p.7</ref> | |||
==Application== | |||
Quaternion algebras are applied in [[number theory]], particularly to [[quadratic form]]s. They are concrete structures that generate the elements of order two in the [[Brauer group]] of ''F''. For some fields, including algebraic number fields, every element of order 2 in its Brauer group is represented by a quaternion algebra. A theorem of [[Alexander Merkurjev]] implies that each element of order 2 in the Brauer group of any field is represented by a tensor product of quaternion algebras.<ref name=Lam139>Lam (2005) p.139</ref> In particular, over [[p-adic field]]s the construction of quaternion algebras can be viewed as the quadratic [[Hilbert symbol]] of [[local class field theory]]. | |||
==Classification== | |||
It is a theorem of [[Ferdinand Georg Frobenius|Frobenius]] that there are only two real quaternion algebras: 2×2 matrices over the reals and Hamilton's real quaternions. | |||
In a similar way, over any [[local field]] ''F'' there are exactly two quaternion algebras: the 2×2 matrices over ''F'' and a division algebra. | |||
But the quaternion division algebra over a local field is usually ''not'' Hamilton's quaternions over the field. For example, over the ''p''-adic numbers Hamilton's quaternions are a division algebra only when ''p'' is 2. For odd prime ''p'', the ''p''-adic Hamilton quaternions are isomorphic to the 2×2 matrices over the ''p''-adics. To see the ''p''-adic Hamilton quaternions are not a division algebra for odd prime ''p'', observe that the congruence ''x''<sup>2</sup> + ''y''<sup>2</sup> = −1 mod ''p'' is solvable and therefore by [[Hensel's lemma]] — here is where ''p'' being odd is needed — the equation | |||
:''x''<sup>2</sup> + ''y''<sup>2</sup> = −1 | |||
is solvable in the ''p''-adic numbers. Therefore the quaternion | |||
:''xi'' + ''yj'' + ''k'' | |||
has norm 0 and hence doesn't have a multiplicative inverse. | |||
One would like to classify the [[Algebra homomorphism|''F''-algebra isomorphism]] [[equivalence class|classes]] of all quaternion algebras for a given field, ''F''. One way to do this is to use the one-to-one correspondence between isomorphism classes of quaternion algebras over ''F'' and isomorphism classes of their ''norm forms''. | |||
To every quaternion algebra ''A'', one can associate a quadratic form ''N'' (called the ''[[norm form]]'') on ''A'' such that | |||
:<math>N(xy) = N(x)N(y)</math> | |||
for all ''x'' and ''y'' in ''A''. It turns out that the possible norm forms for quaternion ''F''-algebras are exactly the [[Pfister form|Pfister 2-forms]]. | |||
==Quaternion algebras over the rational numbers== | |||
Quaternion algebras over the rational numbers have an arithmetic theory similar to, but more complicated than, that of quadratic extensions of <math>\mathbb{Q}</math>. | |||
Let <math>B</math> be a quaternion algebra over <math>\mathbb{Q}</math> and let <math>\nu</math> be a [[Place (mathematics)|place]] of <math>\mathbb{Q}</math>, with completion <math>\mathbb{Q}_\nu</math> (so it is either the ''p''-adic numbers <math>\mathbb{Q}_p</math> for some prime ''p'' or the real numbers <math>\mathbb{R}</math>). Define <math>B_\nu:= \mathbb{Q}_\nu \otimes_{\mathbb{Q}} B</math>, which is a quaternion algebra over <math>\mathbb{Q}_\nu</math>. So there are two choices for | |||
<math>B_\nu</math>: the 2 by 2 matrices over <math>\mathbb{Q}_\nu</math> or a division algebra. | |||
We say that <math>B</math> is '''split''' (or '''unramified''') at <math>\nu</math> if <math>B_\nu</math> is isomorphic to the 2×2 matrices over <math>\mathbb{Q}_\nu</math>. We say that ''B'' is '''non-split''' (or '''ramified''') at <math>\nu</math> if <math>B_\nu</math> is the quaternion division algebra over <math>\mathbb{Q}_\nu</math>. For example, the rational Hamilton quaternions is non-split at 2 and at <math>\infty</math> and split at all odd primes. The rational 2 by 2 matrices are split at all places. | |||
A quaternion algebra over the rationals which splits at <math>\infty</math> is analogous to a real quadratic field and one which is non-split at <math>\infty</math> is analogous to an imaginary quadratic field. The analogy comes from a quadratic field having real embeddings when the minimal polynomial for a generator splits over the reals and having non-real embeddings otherwise. One illustration of the strength of this analogy concerns unit groups in an order of a rational quaternion algebra: | |||
it is infinite if the quaternion algebra splits at <math>\infty</math>{{Citation needed|date=July 2009}} and it is finite otherwise{{Citation needed|date=July 2009}}, just as the unit group of an order in a quadratic ring is infinite in the real quadratic case and finite otherwise. | |||
The number of places where a quaternion algebra over the rationals ramifies is always even, and this is equivalent to the quadratic reciprocity law over the rationals. | |||
Moreover, the places where ''B'' ramifies determines ''B'' up to isomorphism as an algebra. (In other words, non-isomorphic quaternion algebras over the rationals do not share the same set of ramified places.) The product of the primes at which ''B'' ramifies is called the '''discriminant''' of ''B''. | |||
==See also== | |||
*[[composition algebra]] | |||
*[[cyclic algebra]] | |||
*[[octonion algebra]] | |||
*[[Hurwitz quaternion order]] | |||
*[[Hurwitz quaternion]] | |||
==References== | |||
{{reflist}} | |||
* {{cite book | last1=Gille | first1=Philippe | last2=Szamuely | first2=Tamás | title=Central simple algebras and Galois cohomology | series=Cambridge Studies in Advanced Mathematics | volume=101 | location=Cambridge | publisher=[[Cambridge University Press]] | year=2006 | isbn=0-521-86103-9 | zbl=1137.12001 }} | |||
* {{cite book | first=Tsit-Yuen | last=Lam | authorlink=Tsit Yuen Lam | title=Introduction to Quadratic Forms over Fields | volume=67 | series=Graduate Studies in Mathematics | publisher=[[American Mathematical Society]] | year=2005 | isbn=0-8218-1095-2 | zbl=1068.11023 | mr = 2104929 }} | |||
{{DEFAULTSORT:Quaternion Algebra}} | |||
[[Category:Algebras]] | |||
[[Category:Quaternions|Algebra]] |
Latest revision as of 19:49, 30 March 2013
In mathematics, a quaternion algebra over a field F is a central simple algebra A over F[1][2] that has dimension 4 over F. Every quaternion algebra becomes the matrix algebra by extending scalars (=tensoring with a field extension), i.e. for a suitable field extension K of F, is isomorphic to the 2×2 matrix algebra over K.
The notion of a quaternion algebra can be seen as a generalization of the Hamilton quaternions to an arbitrary base field. The Hamilton quaternions are a quaternion algebra (in the above sense) over (the real number field), and indeed the only one over ℝ apart from the 2×2 real matrix algebra, up to isomorphism.
Structure
Quaternion algebra here means something more general than the algebra of Hamilton quaternions. When the coefficient field F does not have characteristic 2, every quaternion algebra over F can be described as a 4-dimensional F-vector space with basis , with the following multiplication rules:
where a and b are any given nonzero elements of F. From these rules we get:
(The Hamilton quaternions are the case where and a = b = −1.) The algebra defined in this way is denoted (a,b)F or simply (a,b).[3] When F has characteristic 2, a different explicit description in terms of a basis of 4 elements is also possible, but in any event the definition of a quaternion algebra over F as a 4-dimensional central simple algebra over F applies uniformly in all characteristics.
A quaternion algebra (a,b)F is either a division algebra or isomorphic to the matrix algebra of 2×2 matrices over F: the latter case is termed split.[4] The norm form
defines a structure of division algebra if and only if the norm is an anisotropic quadratic form, that is, zero only on the zero element. The conic C(a,b) defined by
has a point (x,y,z) with coordinates in F in the split case.[5]
Application
Quaternion algebras are applied in number theory, particularly to quadratic forms. They are concrete structures that generate the elements of order two in the Brauer group of F. For some fields, including algebraic number fields, every element of order 2 in its Brauer group is represented by a quaternion algebra. A theorem of Alexander Merkurjev implies that each element of order 2 in the Brauer group of any field is represented by a tensor product of quaternion algebras.[6] In particular, over p-adic fields the construction of quaternion algebras can be viewed as the quadratic Hilbert symbol of local class field theory.
Classification
It is a theorem of Frobenius that there are only two real quaternion algebras: 2×2 matrices over the reals and Hamilton's real quaternions.
In a similar way, over any local field F there are exactly two quaternion algebras: the 2×2 matrices over F and a division algebra. But the quaternion division algebra over a local field is usually not Hamilton's quaternions over the field. For example, over the p-adic numbers Hamilton's quaternions are a division algebra only when p is 2. For odd prime p, the p-adic Hamilton quaternions are isomorphic to the 2×2 matrices over the p-adics. To see the p-adic Hamilton quaternions are not a division algebra for odd prime p, observe that the congruence x2 + y2 = −1 mod p is solvable and therefore by Hensel's lemma — here is where p being odd is needed — the equation
- x2 + y2 = −1
is solvable in the p-adic numbers. Therefore the quaternion
- xi + yj + k
has norm 0 and hence doesn't have a multiplicative inverse.
One would like to classify the F-algebra isomorphism classes of all quaternion algebras for a given field, F. One way to do this is to use the one-to-one correspondence between isomorphism classes of quaternion algebras over F and isomorphism classes of their norm forms.
To every quaternion algebra A, one can associate a quadratic form N (called the norm form) on A such that
for all x and y in A. It turns out that the possible norm forms for quaternion F-algebras are exactly the Pfister 2-forms.
Quaternion algebras over the rational numbers
Quaternion algebras over the rational numbers have an arithmetic theory similar to, but more complicated than, that of quadratic extensions of .
Let be a quaternion algebra over and let be a place of , with completion (so it is either the p-adic numbers for some prime p or the real numbers ). Define , which is a quaternion algebra over . So there are two choices for : the 2 by 2 matrices over or a division algebra.
We say that is split (or unramified) at if is isomorphic to the 2×2 matrices over . We say that B is non-split (or ramified) at if is the quaternion division algebra over . For example, the rational Hamilton quaternions is non-split at 2 and at and split at all odd primes. The rational 2 by 2 matrices are split at all places.
A quaternion algebra over the rationals which splits at is analogous to a real quadratic field and one which is non-split at is analogous to an imaginary quadratic field. The analogy comes from a quadratic field having real embeddings when the minimal polynomial for a generator splits over the reals and having non-real embeddings otherwise. One illustration of the strength of this analogy concerns unit groups in an order of a rational quaternion algebra: it is infinite if the quaternion algebra splits at Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. and it is finite otherwisePotter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park., just as the unit group of an order in a quadratic ring is infinite in the real quadratic case and finite otherwise.
The number of places where a quaternion algebra over the rationals ramifies is always even, and this is equivalent to the quadratic reciprocity law over the rationals. Moreover, the places where B ramifies determines B up to isomorphism as an algebra. (In other words, non-isomorphic quaternion algebras over the rationals do not share the same set of ramified places.) The product of the primes at which B ramifies is called the discriminant of B.
See also
References
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