Difference between revisions of "Tamagawa number"
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The volume of a homogeneous space $G_A^{(1)}/G_K$ associated with the group of adèles (cf. [[Adèle|Adèle]]) of a connected [[Linear algebraic group|linear algebraic group]] $G$ defined over a global field $K$ with respect to the [[Tamagawa measure|Tamagawa measure]]. Here $G_A^{(1)}/G_K$ is the subgroup of $G_A$ consisting of those adèles $g = (g_\nu)_{\nu\in V} \in G_A$ for which | The volume of a homogeneous space $G_A^{(1)}/G_K$ associated with the group of adèles (cf. [[Adèle|Adèle]]) of a connected [[Linear algebraic group|linear algebraic group]] $G$ defined over a global field $K$ with respect to the [[Tamagawa measure|Tamagawa measure]]. Here $G_A^{(1)}/G_K$ is the subgroup of $G_A$ consisting of those adèles $g = (g_\nu)_{\nu\in V} \in G_A$ for which | ||
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$$\prod_{\nu \in V} | \chi(g_\nu)|_\nu = 1$$ | $$\prod_{\nu \in V} | \chi(g_\nu)|_\nu = 1$$ | ||
− | for any character $\chi$ of $G$ which is defined over $K$ (the product is taken with respect to all valuations $\nu$ in the set $V$ of normalized valuations of $K$). The finiteness of the Tamagawa number follows from reduction theory (see | + | for any character $\chi$ of $G$ which is defined over $K$ (the product is taken with respect to all valuations $\nu$ in the set $V$ of normalized valuations of $K$). The finiteness of the Tamagawa number follows from reduction theory (see {{Cite|Pl}}). |
When describing the values of $\tau(G)$ it is convenient to distinguish the cases of unipotent groups, algebraic tori and semi-simple groups. For unipotent groups the Tamagawa number is always equal to 1. If $T$ is an algebraic $K$-torus, then | When describing the values of $\tau(G)$ it is convenient to distinguish the cases of unipotent groups, algebraic tori and semi-simple groups. For unipotent groups the Tamagawa number is always equal to 1. If $T$ is an algebraic $K$-torus, then | ||
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$$\tau(T) = { { [H^1(K,\hat T)] }\over{[{\rm Shaf}(T)] } }$$ | $$\tau(T) = { { [H^1(K,\hat T)] }\over{[{\rm Shaf}(T)] } }$$ | ||
− | where $ [H^1(K,\hat T)]$ and $[{\rm Shaf}(T)]$ are the order of the one-dimensional Galois cohomology group of the module of rational characters $\hat T$ of the torus $T$ and the order of its Shafarevich Tate group, respectively. On the basis of this formula an example was constructed of a torus for which $\tau(T)$ is not an integer | + | where $ [H^1(K,\hat T)]$ and $[{\rm Shaf}(T)]$ are the order of the one-dimensional Galois cohomology group of the module of rational characters $\hat T$ of the torus $T$ and the order of its Shafarevich Tate group, respectively. On the basis of this formula an example was constructed of a torus for which $\tau(T)$ is not an integer {{Cite|On}}. The determination of the Tamagawa number of a semi-simple group over a number field can be reduced to the case of a simply-connected group {{Cite|On2}}: Let $G$ be a semi-simple $K$-group, let $\pi : \hat G \to G$ be the universal covering which is defined over $K$, let $F = {\rm Ker}\; \pi$ be the fundamental group of $G$, and let $\hat F$ be its character group; then |
$$\tau(G) = \tau(\hat G) { {h^0(\hat F) }\over{i^1(\hat F)}},$$ | $$\tau(G) = \tau(\hat G) { {h^0(\hat F) }\over{i^1(\hat F)}},$$ | ||
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where $h^0(\hat F) = [H^0(K,F)]$, and $i^1(\hat F)$ is the order of the kernel of the canonical mapping | where $h^0(\hat F) = [H^0(K,F)]$, and $i^1(\hat F)$ is the order of the kernel of the canonical mapping | ||
$$H^1(K,\hat F) \to \prod_{\nu\in V} H^1(K_\nu,\hat F).$$ | $$H^1(K,\hat F) \to \prod_{\nu\in V} H^1(K_\nu,\hat F).$$ | ||
− | It is the conjectured that for all simply-connected groups the Tamagawa number is equal to 1 (the Weil conjecture). This was proved for most types of simple groups over number fields ( | + | It is the conjectured that for all simply-connected groups the Tamagawa number is equal to 1 (the Weil conjecture). This was proved for most types of simple groups over number fields ({{Cite|We}}, {{Cite|We2}}, {{Cite|Ma}}), and also for Chevalley groups over number fields (see {{Cite|}}) and over global function fields {{Cite|Ha}}. |
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The Shafarevich Tate group is also called Tate Shafarevich group; cf. [[Galois cohomology|Galois cohomology]] for its definition. | The Shafarevich Tate group is also called Tate Shafarevich group; cf. [[Galois cohomology|Galois cohomology]] for its definition. | ||
− | + | For the relation between $\tau(G)$ and $\tau(\hat G)$ see {{Cite|Ko}}. | |
− | For the relation between $\tau(G)$ and $\tau(\hat G)$ see | + | Weil's conjecture has been proved by R. Kottwitz {{Cite|Ko2}} for number fields, modulo the validity of the [[Hasse principle|Hasse principle]]. (The latter has also been established.) |
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− | Weil's conjecture has been proved by R. Kottwitz | ||
====References==== | ====References==== | ||
− | + | {| | |
+ | |- | ||
+ | |valign="top"|{{Ref|CaFr}}||valign="top"| J.W.S. Cassels (ed.) A. Fröhlich (ed.), ''Algebraic number theory'', Acad. Press (1967) {{MR|0215665}} {{ZBL|0153.07403}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|Ha}}||valign="top"| G. Harder, ''Chevalley groups over function fields and automorphic forms'' Ann. of Math., '''100''' (1974) pp. 249 306 {{MR|0563090}} {{ZBL|0309.14041}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|Ko}}||valign="top"| R.E. Kottwitz, ''Stable trace formula: cuspidal tempered terms'' Duke Math. J., '''51''' (1984) pp. 611 650 {{MR|0757954}} {{ZBL|0576.22020}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|Ko2}}||valign="top"| R.E. Kottwitz, ''Tamagawa numbers'' Ann. of Math., '''127''' (1988) pp. 629 646 {{MR|0942522}} {{ZBL|0678.22012}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|Ma}}||valign="top"| J.G.M. Mars, ''The Tamagawa number of ${}^2A_n$'' Ann. of Math., '''89''' (1969) pp. 557 574 {{MR|0263828}} {{ZBL|0193.21502}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|On}}||valign="top"| T. Ono, ''On the Tamagawa number of algebraic tori'' Ann. of Math., '''78''' (1963) pp. 47 73 {{MR|0156851}} {{ZBL|0122.39101}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|On2}}||valign="top"| T. Ono, ''On the relative theory of Tamagawa numbers'' Ann. of Math., '''82''' (1965) pp. 88 111 {{MR|0177991}} {{ZBL|0135.08804}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|Pl}}||valign="top"| V.P. Platonov, ''Arithmetic theory of algebraic groups'' Russian Math. Surveys, '''37''' : 3 (1982) pp. 1 62 ''Uspekhi Mat. Nauk'', '''37''' : 3 (1982) pp. 3 54 {{MR|0659426}} {{ZBL|0513.20028}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|We}}||valign="top"| A. Weil, ''Sur certains groupes d'opérateurs unitaires'' Acta Math., '''111''' (1964) pp. 143 211 {{MR|0165033}} {{ZBL|0203.03305}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|We2}}||valign="top"| A. Weil, ''Sur la formule de Siegel dans la théorie des groupes classiques'' Acta Math., '''113''' (1965) pp. 1 87 {{MR|0223373}} {{ZBL|0161.02304}} | ||
+ | |- | ||
+ | |} |
Latest revision as of 21:31, 4 March 2012
2020 Mathematics Subject Classification: Primary: 20G30 Secondary: 11E7222E55 [MSN][ZBL]
The volume of a homogeneous space $G_A^{(1)}/G_K$ associated with the group of adèles (cf. Adèle) of a connected linear algebraic group $G$ defined over a global field $K$ with respect to the Tamagawa measure. Here $G_A^{(1)}/G_K$ is the subgroup of $G_A$ consisting of those adèles $g = (g_\nu)_{\nu\in V} \in G_A$ for which
$$\prod_{\nu \in V} | \chi(g_\nu)|_\nu = 1$$
for any character $\chi$ of $G$ which is defined over $K$ (the product is taken with respect to all valuations $\nu$ in the set $V$ of normalized valuations of $K$). The finiteness of the Tamagawa number follows from reduction theory (see [Pl]).
When describing the values of $\tau(G)$ it is convenient to distinguish the cases of unipotent groups, algebraic tori and semi-simple groups. For unipotent groups the Tamagawa number is always equal to 1. If $T$ is an algebraic $K$-torus, then
$$\tau(T) = { { [H^1(K,\hat T)] }\over{[{\rm Shaf}(T)] } }$$
where $ [H^1(K,\hat T)]$ and $[{\rm Shaf}(T)]$ are the order of the one-dimensional Galois cohomology group of the module of rational characters $\hat T$ of the torus $T$ and the order of its Shafarevich Tate group, respectively. On the basis of this formula an example was constructed of a torus for which $\tau(T)$ is not an integer [On]. The determination of the Tamagawa number of a semi-simple group over a number field can be reduced to the case of a simply-connected group [On2]: Let $G$ be a semi-simple $K$-group, let $\pi : \hat G \to G$ be the universal covering which is defined over $K$, let $F = {\rm Ker}\; \pi$ be the fundamental group of $G$, and let $\hat F$ be its character group; then
$$\tau(G) = \tau(\hat G) { {h^0(\hat F) }\over{i^1(\hat F)}},$$
where $h^0(\hat F) = [H^0(K,F)]$, and $i^1(\hat F)$ is the order of the kernel of the canonical mapping $$H^1(K,\hat F) \to \prod_{\nu\in V} H^1(K_\nu,\hat F).$$ It is the conjectured that for all simply-connected groups the Tamagawa number is equal to 1 (the Weil conjecture). This was proved for most types of simple groups over number fields ([We], [We2], [Ma]), and also for Chevalley groups over number fields (see ) and over global function fields [Ha].
The Shafarevich Tate group is also called Tate Shafarevich group; cf. Galois cohomology for its definition. For the relation between $\tau(G)$ and $\tau(\hat G)$ see [Ko]. Weil's conjecture has been proved by R. Kottwitz [Ko2] for number fields, modulo the validity of the Hasse principle. (The latter has also been established.)
References
[CaFr] | J.W.S. Cassels (ed.) A. Fröhlich (ed.), Algebraic number theory, Acad. Press (1967) MR0215665 Zbl 0153.07403 |
[Ha] | G. Harder, Chevalley groups over function fields and automorphic forms Ann. of Math., 100 (1974) pp. 249 306 MR0563090 Zbl 0309.14041 |
[Ko] | R.E. Kottwitz, Stable trace formula: cuspidal tempered terms Duke Math. J., 51 (1984) pp. 611 650 MR0757954 Zbl 0576.22020 |
[Ko2] | R.E. Kottwitz, Tamagawa numbers Ann. of Math., 127 (1988) pp. 629 646 MR0942522 Zbl 0678.22012 |
[Ma] | J.G.M. Mars, The Tamagawa number of ${}^2A_n$ Ann. of Math., 89 (1969) pp. 557 574 MR0263828 Zbl 0193.21502 |
[On] | T. Ono, On the Tamagawa number of algebraic tori Ann. of Math., 78 (1963) pp. 47 73 MR0156851 Zbl 0122.39101 |
[On2] | T. Ono, On the relative theory of Tamagawa numbers Ann. of Math., 82 (1965) pp. 88 111 MR0177991 Zbl 0135.08804 |
[Pl] | V.P. Platonov, Arithmetic theory of algebraic groups Russian Math. Surveys, 37 : 3 (1982) pp. 1 62 Uspekhi Mat. Nauk, 37 : 3 (1982) pp. 3 54 MR0659426 Zbl 0513.20028 |
[We] | A. Weil, Sur certains groupes d'opérateurs unitaires Acta Math., 111 (1964) pp. 143 211 MR0165033 Zbl 0203.03305 |
[We2] | A. Weil, Sur la formule de Siegel dans la théorie des groupes classiques Acta Math., 113 (1965) pp. 1 87 MR0223373 Zbl 0161.02304 |
Tamagawa number. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Tamagawa_number&oldid=19841