References

Koszul algebras, Veronese subrings and rings with linear ... J. Math. Phys., 28:438–444, 1987. [11] A. Connes. Non-commutative differential geometry. Publ.
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References [1] H. Araki. Indecomposable representations with invariant inner product. Commun. Math. Phys., 97:149–159, 1985. [2] M. Artin and W.F. Schelter. Graded algebras of global dimension 3. Adv. Math., 66:171–216, 1987. [3] J. Backelin and R. Fr¨oberg. Koszul algebras, Veronese subrings and rings with linear resolutions. Revue Roumaine de Math. Pures et App., 30:85–97, 1985. [4] C. Becchi, A. Rouet, and R. Stora. Renormalization of gauge theories. Ann. Phys., 98:287–321, 1976. [5] X. Bekaert and N. Boulanger. Tensor gauge fields in arbitrary representations of GL(D, R). Duality and Poincar´e lemma. Commun. Math. Phys., 245:27–67, 2004. [6] R. Berger. Koszulity for nonquadratic algebras. J. Algebra, 239:705–734, 2001. [7] R. Berger. La cat´egorie gradu´ee. 2002. [8] R. Berger, M. Dubois-Violette, and M. Wambst. Homogeneous algebras. J. Algebra, 261:172–185, 2003. [9] J. Bichon. N-complexes et alg`ebres de Hopf. C.R. Acad. Sci. Paris, S´erie I, 337:441– 444, 2003. [10] A.D. Browning and D. McMullan. The Batalin-Fradkin-Vilkovisky formalism for higher-order theories. J. Math. Phys., 28:438–444, 1987. [11] A. Connes. Non-commutative differential geometry. Publ. IHES, 62:257–360, 1986. [12] A. Connes. Non-commutative geometry. Academic Press, 1994. [13] A. Connes and M. Dubois-Violette. Yang-Mills algebra. Lett. Math. Phys., 61:149–158, 2002. [14] T. Damour and S. Deser. Geometry of spin 3 gauge theories. Ann. Inst. H. Poincar´e, 47:277–307, 1987. [15] B. de Wit and D.Z. Freedman. Systematics of higher-spin gauge fields. Phys. Rev., D21:358–367, 1980. [16] P. Deligne and J. Milne. Tannakian categories. In Lecture Notes in Math., number 900, pages 101–228. Springer Verlag, 1982.

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[17] M. Dubois-Violette. Equations de Yang et Mills, mod`eles σ `a deux dimensions et g´en´eralisations. In L. Boutet de Monvel, A Douady, and J.L. Verdier, editors, Math´ematique et Physique, S´eminaire de l’E.N.S., Paris, 1979/1982, pages 43–64. Progr. Math. 37, Birkh¨auser, 1983. [18] M. Dubois-Violette. Syst`emes dynamiques contraints : L’approche homologique. Ann. Inst. Fourier Grenoble, 37:45–57, 1987. [19] M. Dubois-Violette. Generalized differential spaces with dN = 0 and the q-differential calculus. Czech. J. Phys., 46:1227–1233, 1996. [20] M. Dubois-Violette. dN = 0: Generalized homology. K-Theory, 14:371–404, 1998. [21] M. Dubois-Violette. Generalized homologies for dN = 0 and graded q-differential algebras. In M. Henneaux, J. Krasil’shchik, and A. Vinogradov, editors, Secondary calculus and cohomological physics (Moscow, 1997), pages 69–79. Contemp. Math. 219, American Mathematical Society, 1998. [22] M. Dubois-Violette. Lectures on differentials, generalized differentials and on some examples related to theoretical physics. In Quantum symmetries in theoretical physics and mathematics (Bariloche 2000), pages 59–94. Contemp. Math. 294, American Mathematical Society, 2002. [23] M. Dubois-Violette and M. Henneaux. Generalized cohomology for irreducible tensor fields of mixed Young symmetry type. Lett. Math. Phys., 49:245–252, 1999. [24] M. Dubois-Violette and M. Henneaux. Tensor fields of mixed Young symmetry type and N-complexes. Commun. Math. Phys., 226:393–418, 2002. [25] M. Dubois-Violette and R. Kerner. Universal q-differential calculus and q-analog of homological algebra. Acta Math. Univ. Comenianae, LXV, 2:175–188, 1996. [26] M. Dubois-Violette and T. Popov. Homogeneous algebras, statistics and combinatorics. Lett. Math. Phys., 61:159–170, 2002. [27] M. Dubois-Violette and I.T. Todorov. Generalized cohomologies and the physical subspace of the SU (2) WZNW model. Lett. Math. Phys., 42:183–192, 1997. [28] M. Dubois-Violette and I.T. Todorov. Generalized homologies for the zero modes of the SU (2) WZNW model. Lett. Math. Phys., 48:323–338, 1999. [29] J.M.L. Fisch, M. Henneaux, J. Stasheff, and C. Teitelboim. Existence, uniqueness and cohomology of the classical BRST charge with ghosts. Commun. Math. Phys., 120:379–407, 1989. [30] E.S. Fradkin and G.A. Vilkovisky. Quantization of relativistic systems with constraints. Phys. Lett., B55:224–226, 1975. 2

[31] C. Frondsal. Massless fields with integer spins. Phys. Rev., D18:3624, 1978. [32] W. Fulton. Young tableaux. Cambridge University Press, 1997. [33] J. Gasqui. Sur les structures de courbure d’ordre 2 dans Rn . J. Differential Geometry, 12:493–497, 1977. [34] M. Gerstenhaber. The cohomology structure of an associative ring. Ann. Math., 78:267–287, 1963. [35] H.S. Green. A generalized method of field quantization. Phys. Rev., 90:270–273, 1953. [36] W. Greub, S. Halperin, and R. Vanstone. Connections, curvature, and cohomology Vol III. Academic Press, 1976. [37] A. Guichardet. Complexes de Koszul. 2001. [38] M. Henneaux. Hamiltonian form of the path integral for theories with a gauge freedom. In Physics Reports, number 126, pages 1–66. North Holland, 1985. [39] M. Henneaux and C. Teitelboim. Quantization of gauge systems. Princeton University Press, 1992. [40] M.M. Kapranov. On the q-analog of homological algebra. Preprint Cornell University 1991; q-alg/96/11005. [41] M. Karoubi. Homologie cyclique des groupes et alg`ebres. C.R. Acad. Sci. Paris, S´erie I, 297:381–384, 1983. [42] M. Karoubi. Homologie cyclique et K-th´eorie, volume 149 of Ast´erique. Soci´et´e Math´ematique de France, 1987. [43] C. Kassel and M. Wambst. Alg`ebre homologique des N -complexes et homologies de Hochschild aux racines de l’unit´e. Publ. RIMS, Kyoto Univ., 34:91–114, 1998. [44] J.L. Koszul. Homologie et cohomologie des alg`ebres de Lie. Bull. Soc. Math. Fr., 78:65–127, 1950. [45] A. Lascoux and M.P. Sch¨ utzenberger. Le mono¨ıde plaxique. Quaderni de ”La ricerca scientifica”, 109:129–156, 1981. [46] J.L. Loday. Cyclic homology. Springer Verlag, New York, 1992. [47] J.L. Loday. Notes on Koszul duality for associative algebras. 1999. [48] Yu.I. Manin. Some remarks on Koszul algebras and quantum groups. Ann. Inst. Fourier, Grenoble, 37:191–205, 1987. [49] Yu.I. Manin. Quantum groups and non-commutative geometry. 1988. 3

[50] T. Masson. G´eom´etrie non commutative et applications `a la th´eorie des champs. Th`ese, Orsay, LPT-ORSAY 95-82 ; ESI-296., 1995. [51] M. Mayer. A new homology theory I. Ann. of Math., 43:370–380, 1942. [52] M. Mayer. A new homology theory II. Ann. of Math., 43:594–605, 1942. [53] S.B. Priddy. Koszul resolutions. Trans. Amer. Math. Soc., 152:39–60, 1970. [54] M. Rosso. Espace des phases r´eduit et cohomologie B.R.S. Adv. Ser. Math. Phys., 4:263–269, 1988. [55] A. Sitarz. On the tensor product construction for q-differential algebras. Lett. Math. Phys., 44:17–21, 1998. [56] J.D. Stasheff. Constrained hamiltonians: a homological approach. In Proc. Winter School on Geometry and Physics, pages 239–252. Suppl. Rendiconti del Circ. Mat. di Palermo, 1987. [57] J.D. Stasheff. Homological (ghost) methods in mathematical physics. In R. Coquereaux, M. Dubois-Violette, and P. Flad, editors, Infinite dimensional geometry, non commutative geometry, operator algebras, fundamental interactions. SaintFrancois, Guadeloupe, 1993, World Scientific, 1995. [58] R. Stora. Algebraic structure of chiral anomalies. In New perspectives in quantum field theories. Jaca, Spain, World Scientific, 1986. [59] M. Van den Bergh. A relation between Hochschild homology and cohomology for Gorenstein rings. Proc. Amer. Math. Soc., 126:1345–1348, 1998. [60] M. Van den Bergh. Erratum. Proc. Amer. Math. Soc., 130:2809–2810, 2002. [61] M. Wambst. Homologie cyclique et homologie simpliciale aux racines de l’unit´e. KTheory, 23:377–397, 2001. [62] C.A. Weibel. An introduction to homological algebra. Cambridge University Press, 1994.

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