Quadratic field: Difference between revisions
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An odd prime ''p'' [[ramification|ramifies]] iff ''p'' divides ''d''. Otherwise, ''p'' splits or is inert according as the [[Legendre symbol]] <math>\left(\frac{d}{p}\right)</math> is +1 or -1 respectively. | An odd prime ''p'' [[ramification|ramifies]] iff ''p'' divides ''d''. Otherwise, ''p'' splits or is inert according as the [[Legendre symbol]] <math>\left(\frac{d}{p}\right)</math> is +1 or -1 respectively. | ||
==Galois group== | |||
The extension ''F''/'''Q''' is generated by the roots of <math>X^2 - d</math> and both roots lie in the field, which is thus a [[splitting field]] and so a [[Galois extension]]. The [[Galois group]] is cyclic of order two, with the non-trivial element being the [[field automorphism]] | |||
:<math>x + y\sqrt d \mapsto x - y\sqrt d .\,</math> | |||
If ''F'' is a complex quadratic field then this automorphism is induced by [[complex conjugation]]. | |||
==References== | ==References== |
Revision as of 13:40, 7 December 2008
In mathematics, a quadratic field is a field which is an extension of its prime field of degree two.
In the case when the prime field is finite, so is the quadratic field, and we refer to the article on finite fields. In this article we treat quadratic extensions of the field Q of rational numbers.
In characteristic zero, every quadratic equation is soluble by taking one square root, so a quadratic field is of the form for a non-zero non-square rational number d. Multiplying by a square integer, we may assume that d is in fact a square-free integer.
Ring of integers
As above, we take d to be a square-free integer. The maximal order of F is
unless in which case
Discriminant
The field discriminant of F is d if and otherwise 4d.
Unit group
Class group
Splitting of primes
The prime 2 is ramified if . If then 2 splits into two distinct prime ideals, and if then 2 is inert.
An odd prime p ramifies iff p divides d. Otherwise, p splits or is inert according as the Legendre symbol is +1 or -1 respectively.
Galois group
The extension F/Q is generated by the roots of and both roots lie in the field, which is thus a splitting field and so a Galois extension. The Galois group is cyclic of order two, with the non-trivial element being the field automorphism
If F is a complex quadratic field then this automorphism is induced by complex conjugation.
References
- A. Fröhlich; M.J. Taylor (1991). Algebraic number theory. Cambridge University Press, 175-193,220-230,306-309. ISBN 0-521-36664-X.
- I.N. Stewart; D.O. Tall (1979). Algebraic number theory. Chapman and Hall, 59-62. ISBN 0-412-13840-9.
- Pierre Samuel (1972). Algebraic number theory. Hermann/Kershaw, 34-36.