Non UBC
DSpace
Dranishnikov, Alexander
2014-08-06T23:53:55Z
2013-08-05
In his book dedicated to Gelfand’s 80th anniversary [G] Gromov in- troduced the notion of macroscopic dimension and proposed a conjecture: The macroscopic dimension dimmcM ̃ of the universal cover M ̃ of a closed n-manifold with positive scalar curvature is at most n − 2. We proved this conjecture in [BD] for spin manifolds whose fundamental group sat- isfies the Analytic Novikov Conjecture and the following K-theoretic condition (the Rosenberg-Stolz condition [RS]): ko∗(π) −→ KO∗(π) is a monomorphism. In this presentation we will discuss the inequality dimmcM ̃ < n for for closed positive scalar curvature n-manifolds M. In particular, we prove it for manifolds whose fundamental group satisfies the Analytic Novikov Conjecture and the weaker K-theoretic condition: kolf (Eπ) −→ KOlf (Eπ) is a monomorphism. This allows to to prove the Gromov Conjecture for manifolds with the fundamental groups sat- isfying the Novikov conjecture which are duality groups. The inequality dimmcM ̃ < n is related to Gong-Yu’s concept of a macroscopically large manifold as well as to Gromov’s notion of inessential manifolds. We show that this inequality means exactly that M ̃ is macroscopically large integrally. The large obstacle on the way to the Gromov conjecture is the difference between rational and integral versions of these concepts. The\\r\\n2\\r\\nrational inessentiality means that f∗([M]) = 0 in Hn(Bπ;Q). In the case of a spin manifold with positive scalar curvature the rational inessential- ity follows from Rosenberg’s theorem [R] and the K-homology Chern character. In [G] Gromov conjectured that the condition dimmcM ̃ < n implies the rational inessentiality. It turns out that this his conjecture is closely related to the question of amenability of the fundamental group [Dr2] and generally has a counterexample [Dr3].\\r\\n\\r\\nReferences:\\r\\n[BD] D. Bolotov, A. Dranishnikov, On Gromov’s scalar curvature con- jecture, Proc. of AMS, 138 no. 4 (2010), 1517-1524\\r\\n[Dr2] A. Dranishnikov, Macroscopic dimension and essential manifolds, Proceedings of Steklov Math. Institute, 273 (2011), 41-53.\\r\\n[Dr3] A. Dranishnikov, On macroscopic dimension of rationally essential mani- folds. Geometry and Topology. 15 (2011), no. 2, 1107-1124.\\r\\n[G] M. Gromov, Positive curvature, macroscopic dimension, spectral gaps and higher signatures, Functional analysis on the eve of the 21st century. Vol II, Birhauser, Boston, MA, 1996.\\r\\n[RS] J. Rosenberg, S. Stolz, Metrics of positive scalar curvature and connections with surgery, in: Surveys on Surgery Theory (vol. 2), S. Cappell, A. Ranicki, J. Rosenberg (eds.), Annals of Mathematical Stud- ies 149 (2001), Princeton University Press.\\r\\n[R] J. Rosenberg C∗-algebras, positive scalar curvature, and the Novikov con- jecture, III , Topology 25 (1986), 319 - 336\\r\\n
https://circle.library.ubc.ca/rest/handle/2429/49422?expand=metadata
41 minutes
video/mp4
Author affiliation: University of Florida
10.14288/1.0043476
eng
Unreviewed
Vancouver : University of British Columbia Library
Banff International Research Station for Mathematical Innovation and Discovery
Attribution-NonCommercial-NoDerivs 2.5 Canada
http://creativecommons.org/licenses/by-nc-nd/2.5/ca/
Faculty
BIRS Workshop Lecture Videos (Banff, Alta)
Mathematics
Differential geometry
Manifolds and cell complexes
Scalar curvature, macroscopic dimension and inessential manifolds
Moving Image
http://hdl.handle.net/2429/49422