Hochschild / cyclic seminar at Copenhagen

This is a record of the research seminar we run at University of Copenhagen in 2013.

Talks

September 25: Makoto talked about the comparison of cup products in group cohomology and cyclic cohomology of group algebra.

September 6: Markus continued about the topological / categorical computation of the (homotopy) center of simplicial categories. Note by Makoto.

August 6: Makoto gave an expository talk on “Kontsevich’s graph complex, GRT, and the deformation complex of the sheaf of polyvector fields” arXiv:1211.4230 by Dolgushev, Rogers, and Willwacher. Note by Makoto.

July 2: Angela talked about the natural operations on Hochschild chains of commutative Frobenius algebras. Her note.

June 24: Kristian talked about the cyclic and Hochschild groups of the group rings.

June 19: Markus talked about the topological / categorical approach to the HH⁰. Note taken by Makoto.

May 29: Nathalie talked about the diagramatic proof of the Cartan homotopy formula. Note taken by Makoto. Next seminar is June 19 or 20.

May 2: Makoto talked about the application of Cartan caluculus to the noncommutative torus. Note taken by Makoto.

April 25: Makoto talked about the Cartan calculus on the cyclic complex based on Getzler’s paper. Note by Makoto.

April 11: Rasmus talked about the X-complex approach to the noncummutative torus based on Nekljudova’s thesis. The next seminar will be at Thursday 25 April 10:15 AM (04.4.1), about the noncommutative Cartan calculus by Makoto.

April 4: Tyrone talked about the X-complex formalism of Cuntz-Quillen. Note taken by Makoto. The next seminar will be at Thursday 11 April 1:00 PM, about the X-complex of the NC-torus by Rasmus.

March 15: Ryszard gave an introductory talk. Note taken by Makoto. The next seminar will be on the first week of April. We will start from different calculations of cyclic (co)homology for the noncommutative torus.

Preparation

Early March: Below is a quick summary of the subjects I compiled for brainstorming, and initially circualted as an email to peers.

As a start, below is a short summary of the (algebraic) Hochschild / cyclic (co)homology theories. It’s done in hurry and no wonder heavily biased to my preference, so feel free to add your input. I tried to indicate the references at the bottom, but I appreciate if you could expand that as well.

0.

You could say that there are two large camps studying the Hochschild / cyclic (co)homology theories: the noncommutative differential geometry (NCDG) a la Connes, Cuntz-Quillen…, and the noncommutative calculus (NCC) a la Tsygan, Kontsevich…

1. NCDG

The emphasis is more on the relation with the K-groups. So, the periodic cyclic groups HP_∗(A) and HP^∗(A) are very important. On the Hochschild side, the Hochschild homology complex C_∗(A, A) with coefficient A, and its dual complex, the Hochschild cohomology complex C^∗(A, A^∗) with coefficient A^∗. These correspond to the differential forms and currents, which are receptacles of the “Chern characters”.

Applications are mainly to foliations and index theory things, which are approachable from the operator algebras. It often becomes a problem to find a suitable algebra which is large enough to K-theoretically coincide with the C*-algebra, at the same time small enough to support interesting cocycles. Connes’s “transverse fundamental class” paper is a tour de force containing many important ideas in this regard. The local index formula for spectral triples (Connes-Moscovici, Higson’s survey is more accessible) can be regarded as an variation of the Atiyah-Singer index formula in this context. I should mention application to the Novikov conjecture by Connes-Moscovici. Boris also gave a SYM lecture about it some time ago.

Systematic computation is done for commutative algebras (Hochschild-Kostant-Rosenberg, Connes) and group algebras (Karoubi, Burghelea; in Loday’s book), to name a few.

From the viewpoint of relativising the index theory, there’s the bivariant theory of Cuntz-Quillen. This has some relation to the KK-theory / E-theory also.

Compared to the NCC, you often want to work with non-formal deformation.

The references are Loday’s old book (more on the homology side, also with topological viewpoint) and Cuntz’s surveys (also on the cohomology side, plus bivariant things).

2. NCC

The emphasis is more on the Hochschild cohomology complex C^∗(A, A) with the coefficient A, which is a generalization of the polyvector fields. Deformation quantization is the principal target, so the comparison (‘formality’) to more geometric constructions such as the Poisson (co)homology is important. When the deformation comes into play, it’s mostly formal. This field is littered by so many conjectures (which is both good and bad).

Cartan calculus is an important formalism here. First, there was the Cartan homotopy formula by Getzler, later by Nest-Tsygan, Daletsky-Tsygan, Tamarkin-Tsygan, etc. The (homotopy) Batalin-Vilkovisky algebra is the keyword. This leads to the Gauss-Manin connection on periodic cyclic theory. Capturing Connes’s B-differential was somewhat (still ongoing?) problem here. The introduction of Tamarkin-Tsygan is probably a good entry point.

For the sake of formality, the operadic approach is also important here. There’s Loday-Vallette’s book about the algebraic approach to operads in general. Kontsevich-Soibelman have several surveys with many conjectures, but some of them might be getting outdated (in terms of what is proved and what is not). Hinich’s “Tamarkin’s proof of Kontsevich formality” might be a good motivating start. And Dolgushev-Tamarkin-Tsygan.

For deformation quantization, there’s Dolgushev’s work on Van den Bergh duality, which is a nice application of NCC to NCDG.

3. interactions between NCDG and NCC

3.1. NCDG → NCC

There’s Nest-Tsygan’s algebraic index theorem.

3.2 NCC → NCDG

The Gauss-Manin connection should be one such. Also, there are several things first proved in the formal deformation setting and then brought to the strict deformation setting. Dolgushev’s Van den Bergh duality theorem.

4 What to do in our seminar?

• Fix some literature(s) and proceed step by step?
• Cyclic / Hochschild computations of the noncommutative torus? The definition is not so complicated. This is also a good toy model for operator algebra, Poisson deformation quantization, etc. There are many ways to compute those and you can have some motivation from the geometry of 2-torus, discrete group Z^2 etc, I hope. There’s Connes’s original computation. Nekljudova did X-complex computation (Cuntz’s approach). These two are NCDG approaches. There is also a Gauss-Manin connection argument, which is more of a NCC approach.

References

1. Alain Connes, Noncommutative differential geometry, Inst. Hautes Études Sci. Publ. Math. 62 (1985), 257 360. MR 823176 (87i:58162)
2. B. L. Tsygan, Homology of matrix Lie algebras over rings and the Hochschild homology, Uspekhi Mat. Nauk 38 (1983), no. 2(230), 217 218, Translation in Russ. Math. Survey 38(2) (1983), 198 199. MR 695483 (85i:17014)
3. Joachim Cuntz, Quillen s work on the foundations of cyclic cohomology, preprint, 2012. arXiv:1202.5958
4. Joachim Cuntz and Daniel Quillen, Excision in bivariant periodic cyclic cohomology, Invent. Math. 127 (1997), no. 1, 67 98. MR 1423026 (98g:19003)
5. Joachim Cuntz, Cyclic theory and the bivariant Chern-Connes character, Noncommutative geometry, Lecture Notes in Math., vol. 1831, Springer, Berlin, 2004, pp. 73 135. MR 2058473 (2005e:58007)
6. Joachim Cuntz, Cyclic Theory, Bivariant K-Theory and the Bivariant Chern-Connes Character, Cyclic homology in non-commutative geometry, Encyclopaedia of Mathematical Sciences, vol. 121, Springer-Verlag, Berlin, 2004, Operator Algebras and Non-commutative Geometry, II, pp. 1 72. MR 2052770 (2005k:19008)
7. Alain Connes. Cyclic cohomology and the transverse fundamental class of a foliation. In Geometric methods in operator algebras (Kyoto, 1983), volume 123 of Pitman Res. Notes Math. Ser., pages 52 144. Longman Sci. Tech., Harlow, 1986. MR 866491 (88k:58149)
8. Nigel Higson. The local index formula in noncommutative geometry. In Contemporary developments in algebraic K-theory, ICTP Lect. Notes, XV, pages 443 536 (electronic). Abdus Salam Int. Cent. Theoret. Phys., Trieste, 2004. MR 2175637 (2006m:58039)
9. Alain Connes and Henri Moscovici, Cyclic cohomology, the Novikov conjecture and hyperbolic groups, Topology 29 (1990), no. 3, 345 388. MR 1066176 (92a:58137)
10. G. Hochschild, Bertram Kostant, and Alex Rosenberg. Differential forms on regular affine algebras. Trans. Amer. Math. Soc., 102:383 408, 1962. MR 0142598 (26 #167)
11. Jean-Louis Loday, Cyclic homology, second ed., Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences], vol. 301, Springer-Verlag, Berlin, 1998, Appendix E by Marìa O. Ronco, Chapter 13 by the author in collaboration with Teimuraz Pirashvili. MR 1600246 (98h:16014)
12. Jean-Louis Loday and Vallette Bruno, Algebraic operads, manuscript, 2012, version 0.999. PDF
13. M. Kontsevich and Y. Soibelman, Notes on A^∞-algebras, A^∞-categories and non-commutative geometry, Homological mirror symmetry, Lecture Notes in Phys., vol. 757, Springer, Berlin, 2009, pp. 153 219. MR 2596638 (2011f:53183)
14. Maxim Kontsevich and Yan Soibelman, Deformation Theory. i, manuscript. PS
15. Maxim Kontsevich, XI Solomon Lefschetz Memorial Lecture series: Hodge structures in non-commutative geometry, Non-commutative geometry in mathematics and physics, Contemp. Math., vol. 462, Amer. Math. Soc., Providence, RI, 2008, Notes by Ernesto Lupercio, pp. 1 21. MR 2444365 (2009m:53236)
16. Vladimir Hinich, Tamarkin s proof of Kontsevich formality theorem, Forum Math. 15 (2003), no. 4, 591 614. MR 1978336 (2004j:17029)
17. Ezra Getzler, Cartan homotopy formulas and the Gauss-Manin connection in cyclic homology, Quantum deformations of algebras and their representations (Ramat-Gan, 1991/1992; Rehovot, 1991/1992), Israel Math. Conf. Proc., vol. 7, Bar-Ilan Univ., Ramat Gan, 1993, pp. 65 78. MR 1261901 (95c:19002)
18. Ryszard Nest and Boris Tsygan, On the cohomology ring of an algebra, Advances in geometry, Progr. Math., vol. 172, Birkhäuser Boston, Boston, MA, 1999, pp. 337 370. MR 1667686 (99k:16018)
19. Yu. L. Daletskii and B. L. Tsygan, Operations on Hochschild and cyclic complexes, Methods Funct. Anal. Topology 5 (1999), no. 4, 62 86. MR 1773904 (2001h:16009)
20. D. Tamarkin and B. Tsygan, Noncommutative differential calculus, homotopy BV algebras and formality conjectures, Methods Funct. Anal. Topology 6 (2000), no. 2, 85 100. MR 1783778 (2001i:16017)
21. Vasiliy Dolgushev, The Van den Bergh duality and the modular symmetry of a Poisson variety, Selecta Math. (N.S.) 14 (2009), no. 2, 199 228. MR 2480714 (2009m:53235)
22. Vasiliy Dolgushev, Dmitry Tamarkin, and Boris Tsygan, Formality theorems for Hochschild complexes and their applications, Lett. Math. Phys. 90 (2009), no. 1–3, 103 136. MR 2565036 (2011b:53221)
23. Ryszard Nest and Boris Tsygan. Algebraic index theorem. Comm. Math. Phys., 172(2):223 262, 1995. MR 1350407 (96j:58163b)
24. Valentina Nekljudova, Cyclic and Hochschild homology of one-relator algebras via the X-complex of Cuntz and Quillen, Ph.D. thesis, Universität Münster, 2004. PDF