Difference between revisions of "Unramified character"
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− | From global class field theory it follows that these two definitions of being unramified at a point | + | A character (cf. [[Character of a group|Character of a group]]) of the [[Galois group|Galois group]] $ G ( K / k ) $ |
+ | of a Galois extension of local fields $ K / k $ | ||
+ | that is trivial on the inertia subgroup. Any unramified character can be regarded as a character of the Galois group of the extension $ K _ { \mathop{\rm unr} } / k $, | ||
+ | where $ K _ { \mathop{\rm unr} } $ | ||
+ | is the maximal unramified subfield of the extension $ K / k $. | ||
+ | The unramified characters form a subgroup of the group of all characters. A character of the multiplicative group $ k ^ {*} $ | ||
+ | of a local field $ k $ | ||
+ | that is trivial on the group of units of $ k $ | ||
+ | is also called unramified. This definition is compatible with the preceding one, because by the fundamental theorem of local [[Class field theory|class field theory]] there is for every Abelian extension of local fields $ K / k $ | ||
+ | a canonical reciprocity homomorphism $ \theta : k ^ {*} \rightarrow G ( K / k ) $ | ||
+ | that enables one to identify the set of characters of the group $ G ( K / k ) $ | ||
+ | with a certain subgroup of the character group of $ k ^ {*} $. | ||
+ | |||
+ | For a Galois extension of global fields $ K / k $ | ||
+ | a character $ \chi $ | ||
+ | of the Galois group $ G ( K / k ) $ | ||
+ | is said to be unramified at a point $ \mathfrak Y $ | ||
+ | of $ k $ | ||
+ | if it remains unramified in the above sense under restriction to the decomposition subgroup of any point $ \mathfrak P $ | ||
+ | of $ K $ | ||
+ | lying over $ \mathfrak Y $. | ||
+ | Similarly, a character $ \chi $ | ||
+ | of the idèle class group $ C ( k) $ | ||
+ | of $ k $ | ||
+ | is called unramified at $ \mathfrak Y $ | ||
+ | if its restriction to the subgroup of units of the completion $ k _ {\mathfrak Y } $ | ||
+ | of $ k $ | ||
+ | relative to $ \mathfrak Y $ | ||
+ | is trivial, where the group $ k _ {\mathfrak Y } ^ {*} $ | ||
+ | is imbedded in the standard way in $ C ( k) $. | ||
+ | |||
+ | From global class field theory it follows that these two definitions of being unramified at a point $ \mathfrak Y $ | ||
+ | are compatible, as in the local case. | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> A. Weil, "Basic number theory" , Springer (1974)</TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> A. Weil, "Basic number theory" , Springer (1974)</TD></TR></table> | ||
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− | |||
====Comments==== | ====Comments==== | ||
See [[Ramified prime ideal|Ramified prime ideal]] and [[Inertial prime number|Inertial prime number]] for the notion of inertia subgroup. | See [[Ramified prime ideal|Ramified prime ideal]] and [[Inertial prime number|Inertial prime number]] for the notion of inertia subgroup. |
Latest revision as of 08:27, 6 June 2020
A character (cf. Character of a group) of the Galois group $ G ( K / k ) $
of a Galois extension of local fields $ K / k $
that is trivial on the inertia subgroup. Any unramified character can be regarded as a character of the Galois group of the extension $ K _ { \mathop{\rm unr} } / k $,
where $ K _ { \mathop{\rm unr} } $
is the maximal unramified subfield of the extension $ K / k $.
The unramified characters form a subgroup of the group of all characters. A character of the multiplicative group $ k ^ {*} $
of a local field $ k $
that is trivial on the group of units of $ k $
is also called unramified. This definition is compatible with the preceding one, because by the fundamental theorem of local class field theory there is for every Abelian extension of local fields $ K / k $
a canonical reciprocity homomorphism $ \theta : k ^ {*} \rightarrow G ( K / k ) $
that enables one to identify the set of characters of the group $ G ( K / k ) $
with a certain subgroup of the character group of $ k ^ {*} $.
For a Galois extension of global fields $ K / k $ a character $ \chi $ of the Galois group $ G ( K / k ) $ is said to be unramified at a point $ \mathfrak Y $ of $ k $ if it remains unramified in the above sense under restriction to the decomposition subgroup of any point $ \mathfrak P $ of $ K $ lying over $ \mathfrak Y $. Similarly, a character $ \chi $ of the idèle class group $ C ( k) $ of $ k $ is called unramified at $ \mathfrak Y $ if its restriction to the subgroup of units of the completion $ k _ {\mathfrak Y } $ of $ k $ relative to $ \mathfrak Y $ is trivial, where the group $ k _ {\mathfrak Y } ^ {*} $ is imbedded in the standard way in $ C ( k) $.
From global class field theory it follows that these two definitions of being unramified at a point $ \mathfrak Y $ are compatible, as in the local case.
References
[1] | A. Weil, "Basic number theory" , Springer (1974) |
Comments
See Ramified prime ideal and Inertial prime number for the notion of inertia subgroup.
Unramified character. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Unramified_character&oldid=49095