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A Schwartz type algebra for the tangent groupoid 197Recall that we have well-defined evaluation morphisms as in (7) and (8). In thecase of the tangent groupoid they are by definition morphisms of algebras. Hence, thealgebra S c .G T / is a field of algebras over the closed interval Œ0; 1, with associatedfiber algebras,S.AG / at t D 0, and Cc 1 .G / for t ¤ 0.It is very interesting to see what this means in the examples given in 3.9.5 Further developmentsLet G G .0/ be a Lie groupoid. In index theory for Lie groupoids the tangent groupoidhas been used to define the analytic index associated to the group, as a morphismK 0 .A G / ! K 0 .Cr .G // (see [19]) or as a KK-element in KK.C 0.A G /; Cr .G //(see [13]), this can be done because one has the following short exact sequence ofC -algebras0 ! Cr .G .0; 1/ ! C r .G T / e 0! C 0 .A G / ! 0; (9)and because of the fact that the K-groups of the algebra Cr .G .0; 1/ vanish (homotopyinvariance). The index defined at the C -level has proven to be very useful (seefor example [9]) but extracting numerical invariants from it, with the existent tools, isvery difficult. In non commutative geometry, and also in classical geometry, the toolsfor obtaining more explicit invariants are more developed for the ’smooth objects’; inour case this means the convolution algebra Cc1 .G /, where we can for example applyChern–Weil–Connes theory. Hence, in some way, the indices defined in K 0 .Cc 1 .G //are more refined objects and for some cases it would be preferable to work with them.Unfortunately these indices are not good enough, since for example they are not homotopyinvariant; in [8] Alain Connes discusses this and also other reasons why it is notenough to keep with the Cc 1-indices. The main reason to construct the algebra S c.G T /is that it gives an intermediate way between the Cc1-level and the C -level and willallow us in [5] to define another analytic index morphism associated to the groupoid,with the advantage that this index will take values in a group that allows to do pairingswith cyclic cocycles and in general to apply Chern–Connes theory to it. The way weare going to define our index is by obtaining first a short exact sequence analogous to(9), that is, a sequence of the following kind0 ! J ! S c .G T / e 0! S.A G // ! 0: (10)The problem here will be that we do not dispose of the advantages of the K-theory forC -algebras, since the algebras we are considering are not of this type (we do not havefor example homotopy invariance).References[1] J. Aastrup, S. T. Melo, , B. Monthubert, E. Schrohe, Boutet de Monvel’s Calculus andGroupoids I, Preprint 2006, arxiv:math.KT/0611336.
198 P. Carrillo Rouse[2] J. Aastrup, R. Nest, and E. Schrohe, A continuous field of C -algebras and the tangentgroupoid for manifolds with boundary, J. Funct. Anal. 237 (2006), 482–506.[3] L. Brown, P. Green, and M. Rieffel, Stable isomorphism and stable Morita equivalence forC -algebras, Pacific J. Math. 71 (1977), 349–363.[4] J. Carinena, J. Clemente-Gallardo, E. Follana, J. M. Gracia-Bondia, A. Rivero, and J. C.Varilly, Connes’ tangent groupoid and strict quantization, J. Geom. Phys. 32 (1999), 79–96.[5] P. Carrillo, An analytic index for Lie groupoids, Preprint 2006, arxiv:math.KT/0612455.[6] A. Connes, Sur la théorie non commutative de l’intégration, in Algèbres d’opérateurs,Lecture Notes in Math. 725, Springer-Verlag, Berlin 1979, 19–143.[7] A. Connes, Noncommutative differential geometry, Inst. Hautes Études Sci. Publ. Math. 62(1985), 257–360.[8] A. Connes, Non commutative geometry, Academic Press, San Diego, CA, 1994.[9] A. Connes, and G. Skandalis, The longitudinal index theorem for foliations, Publ. Res. Inst.Math 6 (1984), 1139–1183.[10] C. Debord, J. M. Lescure, and V. Nistor, Groupoids and an index theorem for conicalpseudomanifolds, Preprint 2008, arxiv:math.OA/0609438.[11] J. Dixmier, Les C -algèbres et leurs représentations, Cahiers Scientifiques XXIX,Gauthier-Villars, Paris 1964.[12] A. Haefliger, Groupoïdes d’holonomie et classifiants, Astérisque 116 (1982), 70–97.[13] M. Hilsum and G. Skandalis, Morphismes K-orientés d’espaces de feuilles et fonctorialitéen théorie de Kasparov (d’après une conjecture d’A. Connes), Ann. Sci. École Norm. Sup.(4) 20 (1987), 325–390.[14] N. P. Landsman, Quantization and the tangent groupoid, in Operator algebras and mathematicalphysics, Theta, Bucharest 2003, 251–265.[15] R. Lauter, B. Monthubert, and V. Nistor, Pseudodifferential analysis on continuous familygroupoids, Doc. Math 5 (2000), 625–655.[16] R. Melrose, The Atiyah-Patodi-Singer index theorem, Res. Notes in Math. 4, AK Peters,Wellesley, MA, 1993.[17] I. Moerdijk, Orbifolds as groupoids: an introduction, in Orbifolds in mathematics andphysics (Madison, WI, 2001), Contemp. Math. 310, Amer. Math. Soc., Providence, RI,205–222.[18] B. Monthubert, Groupoids and Pseudodifferential calculus on manifolds with corners, J.Funct. Anal. 199 (2003), 243–286.[19] B. Monthubert and F. Pierrot, Indice analytique et groupoïdes de Lie, C. R. Acad. Sci. Paris325 (1997), 193–198.[20] S. Moroinau, Adiabatic limits of eta and zeta functions of elliptic operators, Math. Z. 246(2004), 441–471.[21] V. Nistor, A. Weinstein, P. and Xu, Pseudodifferential operators on differential groupoids,Pacific J. Math 189 (1999), 117–152.[22] A. Paterson, Groupoids and inverse semigroups, and their operator algebras, Progr. Math.170, Birkhäuser, Boston, MA, 1999.
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EMS Series of Congress ReportsEMS S
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Editors:Guillermo CortiñasDepartam
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ContentsPreface....................
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IntroductionSince its inception 50
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Introductionxiwith D. Blecher, he c
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Program list of speakers and topics
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Categorical aspects of bivariant K-
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42 A. Bartels, S. Echterhoff, and W
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72 H. Emerson and R. MeyerIn this s
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74 H. Emerson and R. MeyerK-theoret
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76 H. Emerson and R. MeyerExample 4
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78 H. Emerson and R. Meyerand exact
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80 H. Emerson and R. Meyercondition
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82 H. Emerson and R. MeyerAs a resu
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84 H. Emerson and R. MeyerLet h and
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86 H. Emerson and R. MeyerCorollary
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88 H. Emerson and R. Meyer5 Dual-Di
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On K 1 of a Waldhausen categoryFern
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On K 1 of a Waldhausen category 93t
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On K 1 of a Waldhausen category 992
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118 M. Karoubi[35], M. F. Atiyah an
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120 M. Karoubihere by GrK n .A/, ar
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122 M. Karoubi(resp. 1) in A. In th
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124 M. Karoubithe class ˛ of A in
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126 M. Karoubiested in the complex
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128 M. KaroubiThe same method may b
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130 M. KaroubiBy the usual excision
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132 M. KaroubiLet A be a graded twi
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134 M. Karoubithe same ideas as in
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136 M. KaroubiTheorem 6.2. 25 The (
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138 M. KaroubiIn order to show this
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140 M. KaroubiThe following theorem
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142 M. KaroubiWe would like to poin
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144 M. KaroubiZ=n identified with t
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Page 166 and 167: Equivariant cyclic homology for qua
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Page 189 and 190: 174 C. Voigtand using ˇ.x; y/ D .S
Page 191 and 192: 176 C. Voigtalgebra A. The space Cn
Page 193 and 194: 178 C. VoigtKK-theory [16]. Hence,
Page 196 and 197: A Schwartz type algebra for the tan
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Page 219 and 220: 204 J. CuntzConsider the action of
Page 221 and 222: 206 J. Cuntzprime numbers p and q,
Page 223 and 224: 208 J. Cuntz6 Representations as cr
Page 225 and 226: 210 J. CuntzProof. The spectral pro
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Page 229 and 230: 214 J. CuntzProposition 7.4. The K-
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248 U. Bunke, T. Schick, M. Spitzwe
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Parshin’s conjecture revisitedTho
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428 C. WeibelGiven (0.4) and axiom
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430 C. WeibelAs pointed out in the
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432 C. WeibelConsider the cohomolog
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434 C. WeibelWe need to see that th
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List of contributorsArthur Bartels,
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List of participantsNatalia Abad Sa
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