Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-24T15:47:19.697Z Has data issue: false hasContentIssue false
  • English
  • Français

The Trace Formula and Its Applications: An Introduction to the Work of James Arthur

Published online by Cambridge University Press:  20 November 2018

Robert P. Langlands
Robert P. Langlands*
Affiliation:
School of Mathematics Institute for Advanced Study Einstein Drive Princeton, NJ 08540 USA
Rights & Permissions [Opens in a new window]

Extract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

In May, 1999 James Greig Arthur, University Professor at the University of Toronto was awarded the Canada Gold Medal by the National Science and Engineering Research Council. This is a high honour for a Canadian scientist, instituted in 1991 and awarded annually, but not previously to a mathematician, and the choice of Arthur, although certainly a recognition of his greatmerits, is also a recognition of the vigour of contemporary Canadian mathematics.

Keywords

11F7011F7258G25
Type
Research Article
Information
Canadian Mathematical Bulletin , Volume 44 , Issue 2 , 01 June 2001 , pp. 160 - 209
Copyright
Copyright © Canadian Mathematical Society 2001

References

Bibliography of James G. Arthur

[1] The Selberg trace formula for groups of F-rank one. Ann. of Math. 100 (1974), 326385.Google Scholar
[2] Some tempered distributions on groups of real rank one. Ann. of Math. 100 (1974), 553584.Google Scholar
[3] A theorem on the Schwartz space of a reductive Lie group. Proc. Nat. Acad. Sci. 72 (1975), 47184719.Google Scholar
[4] The characters of discrete series as orbital integrals. Invent.Math. 32 (1976), 205261.Google Scholar
[5] A truncation process for reductive groups. Bull. Amer. Math. Soc. 83 (1977), 748750.Google Scholar
[6] Eisenstein series and the trace formula. Proc. Sympos. Pure Math. 33(1979), Part 1, 253274.Google Scholar
[7] A trace formula for reductive groups I: Terms associated to classes in G(Q). Duke Math. J. 245 (1978), 911952.Google Scholar
[8] Harmonic analysis of invariant distributions. Lie theories and their applications (Queen's University, 1977), Queen's Papers in Pure and Appl. Math. 48 (1978), 384393.Google Scholar
[9] A trace formula for reductive groups II: Applications of a truncation operator. Compositio Math. 40 (1980), 87121.Google Scholar
[10] The trace formula in invariant form. Ann. of Math. 114 (1981), 174.Google Scholar
[11] Automorphic representations and number theory. C.M.S. Conf. Proc. 1 (1981), 351.Google Scholar
[12] On the inner product of truncated Eisenstein series. Duke Math. J. 49 (1982), 3570.Google Scholar
[13] On a family of distributions obtained from Eisenstein series I: Application of the Paley-Wiener theorem. Amer. J. Math. 104 (1982), 12431288.Google Scholar
[14] On a family of distributions obtained from Eisenstein series II: Explicit formulas. Amer. J. Math. 104 (1982), 12891336.Google Scholar
[15] A Paley-Wiener theorem for real reductive groups. Acta Math. 150 (1983), 189.Google Scholar
[16] The trace formula for reductive groups. Publ. Math. Univ. Paris VII 15 (1983), 141.Google Scholar
[17] Multipliers and a Paley-Wiener theorem for real reductive groups. Representation Theory of Reductive Groups (Park City, Utah, 1982), Progr. Math. 40 (1983), 119.Google Scholar
[18] On some problems suggested by the trace formula. Lie Group Representations II, Springer Lecture Notes in Math. 1041 (1984), 149.Google Scholar
[19] The trace formula for noncompact quotient. In: Proceedings of International Congress of Mathematicians (Warsaw, 1983), PWN, Warsaw, 1984, 849–859.Google Scholar
[20] A measure on the unipotent variety. Canad. J. Math. 37 (1985), 12371274.Google Scholar
[21] On a family of distributions obtained from orbits. Canad. J. Math. 38 (1986), 179214.Google Scholar
[22] The Fourier transform of weighted orbital integrals on SL(2, R).With R. Herb and P. Sally. Contemp. Math. 53 (1986), 1737.Google Scholar
[23] The characters of supercuspidal representations as weighted orbital integrals. Proc. Indian Acad. Sci. 97 (1987), 319.Google Scholar
[24] The local behaviour of weighted orbital integrals. Duke Math. J. 56 (1988), 223293.Google Scholar
[25] Characters, harmonic analysis, and an L2-Lefschetz formula. Proc. Sympos. Pure Math. 48 (1988), 167179.Google Scholar
[26] The invariant trace formula I. Local theory. J. Amer. Math. Soc. 1 (1988), 323383.Google Scholar
[27] The invariant trace formula II. Global theory. J. Amer. Math. Soc. 1 (1988), 501554.Google Scholar
[28] Intertwining operators and residues I.Weighted characters. J. Funct. Anal. 84 (1989), 1984.Google Scholar
[29] Intertwining operators and residues II. Invariant distributions. Compositio Math. 70 (1989), 5199.Google Scholar
[30] Simple Algebras, Base Change and the Advanced Theory of the Trace Formula.With L. Clozel. Ann. of Math. Stud. 120, Princeton University Press, 1989.Google Scholar
[31] The trace formula and Hecke operators. In: Number Theory, Trace Formulas and Discrete Groups, Academic Press, 1989, 1127.Google Scholar
[32] The L2-Lefschetz numbers of Hecke operators. Invent.Math. 97 (1989), 257290.Google Scholar
[33] Harmonic analysis of tempered distributions on semisimple Lie groups of real rank one. In: Representation Theory and Harmonic Analysis on Semisimple Lie Groups (eds. P. Sally and D. Vogan),Math. SurveysMonographs 31, Amer. Math. Soc., 1989, 13–100.Google Scholar
[34] Unipotent automorphic representations: Conjectures. Astérisque 171–172 (1989), 1371.Google Scholar
[35] Unipotent automorphic representations: Global Motivation. In: Automorphic Forms, Shimura Varieties and L-functions, Vol. I (Ann Arbor, MI, 1988), Perspect.Math. 10 (1989), 175.Google Scholar
[36] Towards a local trace formula. In: Proceedings of First JAMI Conference, Johns Hopkins University Press, 1990, 123.Google Scholar
[37] Lectures on automorphic L-functions. With S. Gelbart. L-functions and Arithmetic (Durham, 1990), London Math. Soc. Lecture Note Ser. 153 (1991), 159.Google Scholar
[38] Some problems in local harmonic analysis. Harmonic Analysis on Reductive Groups (Brunswick, ME, 1989), Progr.Math. 101 (1991), 5778.Google Scholar
[39] A local trace formula. Inst. Hautes Études Sci. Publ. Math. 73 (1991), 596.Google Scholar
[40] On elliptic tempered characters. Acta Math. 171 (1993), 73138.Google Scholar
[41] On the Fourier transforms of weighted orbital integrals. J. Reine Angew. Math. 452 (1994), 163217.Google Scholar
[42] The trace Paley-Wiener theorem for Schwartz functions. Contemp.Math. 177 (1994), 171180.Google Scholar
[43] L2-cohomology and automorphic representations. In: Canadian Mathematical Society 1945–1995, Vol. 3, Canadian Math. Soc., Ottawa, 1996, 1–17.Google Scholar
[44] On local character relations. Selecta Math. 2 (1996), 501579.Google Scholar
[45] The problem of classifying automorphic representations of classical groups. CRM Proc. Lecture Notes 11 (1997), 112.Google Scholar
[46] Stability and endoscopy: informal motivation. Proc. Sympos. Pure Math. 61 (1997), 433442.Google Scholar
[47] Canonical normalization of weighted characters and a transfer conjecture. C. R. Math. Rep. Acad. Sci. Canada 20 (1998), 3552.Google Scholar
[48] Towards a stable trace formula. In: Proceedings of the International Congress of Mathematicians, Vol. II (Berlin, 1998), Doc. Math. 1998, Extra Vol. II, 507–517.Google Scholar
[49] On the transfer of distributions: weighted orbital integrals. Duke Math. J. 99 (1999), 209283.Google Scholar
[50] Endoscopic L-functions and a combinatorial identity. Canad. J. Math. 51 (1999), 11351148.Google Scholar
[51] Stabilization of a family of differential equations. Mathematical Legacy of Harish-Chandra (Baltimore, MD, 1998), Proc. Sympos. Pure Math. 68 (2000), 7795.Google Scholar
[52] Harmonic analysis and group representations. Notices Amer. Math. Soc. 47 (2000), 2634.Google Scholar
[53] A stable trace formula I. General expansions. Preprint.Google Scholar
[54] A stable trace formula II. Global descent. Invent.Math., to appear.Google Scholar
[55] A stable trace formula III. Proof of the main theorems. Preprint.Google Scholar
[56] The principle of functoriality. Submitted to Mathematical Challenges of the 21st Century.Google Scholar

Supplementary References

[ABV] Adams, J., Barbasch, D. and Vogan, D., The Langlands classification and irreducible characters for real reductive groups. Progr. Math. 104, Birkhäuser, 1992.Google Scholar
[CD] Clozel, L. and Delorme, P., Le théorème de Paley-Wiener invariant pour les groupes de Lie réductifs. Invent.Math. 77 (1984), 427453; Sur le théorème de Paley-Wiener invariant pour les groupes de Lie réductifs réels. C. R. Acad. Sci. Paris. Sér. 1 Math. 300 (1985), 331–333.Google Scholar
[HPS] Howe, R. and Piatetski-Shapiro, I., A counterexample to the “generalized Ramanujan conjecture” for (quasi-)split groups. Automorphic forms, representations and L-functions (Corvallis, OR, 1977), Part 1, Proc. Sympos. Pure Math. 33 (1979), 315322.Google Scholar
[J] Jacquet, H., On the residual spectrum of GL(n). Lie Group Representations II, Springer Lecture Notes in Math. 1041 (1984), 185208.Google Scholar
[JL] Jacquet, H. and Langlands, R. P., Automorphic forms on GL(2). Springer Lecture Notes in Math. 114, 1970.Google Scholar
[K1] Kottwitz, R. E., Tamagawa numbers. Ann. of Math. 127 (1988), 629646.Google Scholar
[K2] Kottwitz, R. E., On the ƛ-adic representations associated to some simple Shimura varieties. Invent.Math. 108 (1992), 653665 Google Scholar
[KS] Kottwitz, R. and Shelstad, D., Foundations of twisted endoscopy. Astérisque 255, 1999.Google Scholar
[LL] Labesse, J.-P. and Langlands, R. P., L-indistinguishability for SL(2). Canad. J. Math. 31 (1979), 726785.Google Scholar
[KL] Langlands, R., Les débuts d’une formule des traces stables. Publ. Math. Univ. Paris VII 13, Paris, 1983; R. Kottwitz, Stable trace formula: cuspidal tempered terms. Duke Math. J. 51 (1984), 611650; , Stable trace formula: elliptic singular terms. Math. Ann. 275 (1986), 365–399.Google Scholar
[L] Langlands, R. P., Rank-one residues of Eisenstein series. Israel Math, Conf. Proc. 3 (1990), 111125.Google Scholar
[LS] Langlands, R. P. and Shelstad, D., On the definition of transfer factors.Math. Ann. 278 (1987), 219271.Google Scholar
[Mo] Moeglin, C., Représentations unipotentes et formes automorphes de carré intégrable. Forum Math. 6 (1994), 651744.Google Scholar
[MW] Moeglin, C. and Waldspurger, J.-L., Le spectre résiduel de GL(n). Ann. Sci. École Norm. Sup. 22 (1989), 605674.Google Scholar
[Mü] Müller, W., The trace class conjecture in the theory of automorphic forms. Ann. of Math. 130 (1989), 473529.Google Scholar
[R] Rogawski, J., Automorphic representations of unitary groups in three variables. Ann. of Math. Stud. 123, Princeton University Press, 1990; The multiplicity formula for A-packets. In: The zeta functions of Picard modular surfaces (eds. R. P. Langlands and D. Ramakrishnan), Centre de recherches mathématiques, Univ. de Montréal, 1992, 395–419.Google Scholar
[S] Saito, H., Automorphic forms and extensions of number fields. Lectures in Mathematics 8, Kyoto University, 1975.Google Scholar
[W] Waldspurger, J.-L., Le lemme fondamental implique le transfert. Compositio Math. 105 (1997), 153236.Google Scholar