Square integrable highest weight representations
Glasgow mathematical journal, Tome 39 (1997) no. 3, pp. 296-321

Voir la notice de l'article provenant de la source Cambridge University Press

If G is the group of holomorphic automorphisms of a bounded symmetric domain, then G has a distinguished class of irreducible unitary representations called the holomorphic discrete series of G. These representations have been studied by Harish-Chandra in [7]. On the Lie algebra level, the Harish-Chandra modules corresponding to the holomorphic discrete series representations are highest weight modules. Even for G as above, it turns out that not all the unitary highest weight modules belong to the holomorphic discrete series but there exists a condition on the highest weight which characterizes the holomorphic discrete series among the unitary highest weight representations. They can be defined as those unitary highest weight representations with square integrable matrix coefficients.
Neeb, Karl-Hermann. Square integrable highest weight representations. Glasgow mathematical journal, Tome 39 (1997) no. 3, pp. 296-321. doi: 10.1017/S0017089500032237
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[1] 1.Ali, S. T. and Antoine, J.-P., Quantization and Dequantization, in Quantization and infinite dimensional systems (Eds. Antoine, J.-P. et al. ), Plenum Press, New York, London, 1994. Google Scholar

[2] 2.Bourbaki, N., Groupes et algèbres de Lie, Chapitres 4, 5 et 6 (Masson, Paris, 1981). Google Scholar

[3] 3.Duflo, M., Construction de representations unitaires d'un groupe de Lie, Cours dété de CIME, Cortona 1980. Google Scholar

[4] 4.Duflo, M., Théorie de Mackey pour les groupes algébriques, Ada Math. 149 (1982), 153–213. Google Scholar

[5] 5.Duflo, M., On the Plancherel formula for almost algebraic real Lie groups, Led. Notes in Math. 1077 (1984), Springer, 101–165. Google Scholar | DOI

[6] 6.Guichardet, A., Théorie de Mackey et mdthode des orbites selon M. Duflo, Expositio Math. 3 (1985), 303–346. Google Scholar

[7] 7.Harish-Chandra, , Representations of semi-simple Lie groups, V, VI, Amer. J. Math. 78 (1956), 1–41, 564–628. Google Scholar | DOI

[8] 8.Hilgert, J., Hofmann, K. H. and Lawson, J. D., Lie Groups, Convex Cones, and Semigroups (Oxford University Press, 1989). Google Scholar

[9] 9.Hilgert, J. and Neeb, K.-H., Lie semigroups and their applications, Lecture Notes in Math. 1552 Springer, 1993. Google Scholar

[10] 10.Hilgert, J. and Neeb, K.-H., Compression semigroups of open orbits on complex manifolds, Arkiv for Math. 33 (1995), 293–322. Google Scholar | DOI

[11] 11.Neeb, K.-H., Globality in Semisimple Lie Groups, Annales de Vlnstitut Fourier 40 (1990), 493–536. Google Scholar | DOI

[12] 12.Neeb, K.-H., Invariant subsemigroups of Lie groups, Memoirs of the Amer. Math. Soc. 499 (1993). Google Scholar

[13] 13.Neeb, K.-H., Realization of general unitary highest weight representations, Preprint, Technische Hochschule Darmstadt 1662 (1994). Google Scholar

[14] 14.Neeb, K.-H., Holomorphic representations and coherent states, in Quantization and infinite dimensional systems (Eds. Antoine, J.-P. et al. ), Plenum Press, New York, London, 1994. Google Scholar

[15] 15.Neeb, K.-H., On closedness and simple connectedness of adjoint and coadjoint orbits, Manuscripta Math. 82 (1994), 51–65. Google Scholar | DOI

[16] 16.Neeb, K.-H., Holomorphic representation theory II, Ada math. 173 (1994), 103–133. Google Scholar

[17] 17.Neeb, K.-H., Holomorphic representation theory I, Math. Ann. 301 (1995), 155–181. Google Scholar | DOI

[18] 18.Neeb, K.-H., On the convexity of the moment mapping for unitary highest weight representations, J. Fund. Anal. 127 (1995), 301–325. Google Scholar | DOI

[19] 19.Neeb, K.-H., Kahler structures and convexity properties of coadjoint orbits, Forum Math. 7 (1995), 349–384. Google Scholar | DOI

[20] 20.Neeb, K.-H., A Duistermaat-Heckman formula for admissible coadjoint orbits, Proceedings of “Workshop on Lie Theory and its Applications in Physics”, Clausthal, August, 1995 (Ed. Dobrev, Doebner), to appear. Google Scholar

[21] 21.Neeb, K.-H., Coherent states, holomorphic extensions, and highest weight representations, Pacific J. Math. 174 (1996), 497–542. Google Scholar | DOI

[22] 22.Perelomov, A. M., Generalized coherent states and their applications (Springer, Berlin, 1986). Google Scholar | DOI

[23] 23.Vogan, D., The algebraic structure of the representations of semisimple Lie groups, Annals of Math. 109 (1979), 1–60. Google Scholar | DOI

[24] 24.Wallach, N. R., Real reductive groups I (Academic Press Inc., Boston, New York, Tokyo, 1988). Google Scholar

[25] 25.Warner, G., Harmonic analysis on semisimple Lie groups I (Springer, Berlin, Heidelberg, New York, 1972). Google Scholar

[26] 26.Wildberger, N. J., On the Fourier transform of a compact semisimple Lie group, J. Austral. Math. Soc., Ser. A 56 (1994), 64–116. Google Scholar | DOI

[27] 27.Wolf, J., Unitary representations on partially holomorphic cohomology spaces, Mem. of the Amer. Math. Soc. 138 (1974). Google Scholar

[28] 28.Wolf, J., Classification and Fourier Inversion for parabolic subgroups with square integrable nilradical, Mem. of the Amer. Math. Soc. 225 (1979). Google Scholar

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