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• Special_values_of_L-functions abstract "In mathematics, the study of special values of L-functions is a subfield of number theory devoted to generalising formulae such as the Leibniz formula for pi, namelyby the recognition that expression on the left-hand side is also L(1) where L(s) is the Dirichlet L-function for the Gaussian field. This formula is a special case of the analytic class number formula, and in those terms reads that the Gaussian field has class number 1, and also contains four roots of unity, so accounting for the factor ¼.There are two families of conjectures, formulated for general classes of L-functions (the very general setting being for L-functions L(s) associated to Chow motives over number fields), the division into two reflecting the questions of:(a) how to replace π in the Leibniz formula by some other "transcendental" number (whether or not it is yet possible for transcendental number theory to provide a proof of the transcendence); and(b) how to generalise the rational factor in the formula (class number divided by number of roots of unity) by some algebraic construction of a rational number that will represent the ratio of the L-function value to the "transcendental" factor.Subsidiary explanations are given for the integer values of n for which such formulae L(n) can be expected to hold.The conjectures for (a) are called Beilinson's conjectures, for Alexander Beilinson. The idea is to abstract from the regulator of a number field to some "higher regulator" (the Beilinson regulator), a determinant constructed on a real vector space that comes from algebraic K-theory.The conjectures for (b) are called the Bloch–Kato conjectures for special values (for Spencer Bloch and Kazuya Kato – NB this circle of ideas is distinct from the Bloch–Kato conjecture of K-theory, extending the Milnor conjecture, a proof of which was announced in 2009). For the sake of greater clarity they are also called the Tamagawa number conjecture, a name arising via the Birch–Swinnerton-Dyer conjecture and its formulation as an elliptic curve analogue of the Tamagawa number problem for linear algebraic groups. In a further extension, the equivariant Tamagawa number conjecture (ETNC) has been formulated, to consolidate the connection of these ideas with Iwasawa theory, and its so-called Main Conjecture; it is mathematical folklore that the ETNC and Main Conjecture should be equivalent.All these conjectures are known only in special cases.".
• Special_values_of_L-functions wikiPageExternalLink item?id=JTNB_2003__15_1_179_0.
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• Special_values_of_L-functions wikiPageRevisionID "570267933".
• Special_values_of_L-functions hasPhotoCollection Special_values_of_L-functions.
• Special_values_of_L-functions id "b/b110220".
• Special_values_of_L-functions ide "K/k055000".
• Special_values_of_L-functions title "Beilinson conjectures".
• Special_values_of_L-functions title "K-functor in algebraic geometry".
• Special_values_of_L-functions subject Category:Zeta_and_L-functions.
• Special_values_of_L-functions comment "In mathematics, the study of special values of L-functions is a subfield of number theory devoted to generalising formulae such as the Leibniz formula for pi, namelyby the recognition that expression on the left-hand side is also L(1) where L(s) is the Dirichlet L-function for the Gaussian field.".
• Special_values_of_L-functions label "L-函数の特殊値".
• Special_values_of_L-functions label "Special values of L-functions".
• Special_values_of_L-functions sameAs L-函数の特殊値.
• Special_values_of_L-functions sameAs m.09glpm7.
• Special_values_of_L-functions sameAs Q7574878.
• Special_values_of_L-functions sameAs Q7574878.
• Special_values_of_L-functions wasDerivedFrom Special_values_of_L-functions?oldid=570267933.
• Special_values_of_L-functions isPrimaryTopicOf Special_values_of_L-functions.