The inclusion of configuration spaces of surfaces in Cartesian products, its induced homomorphism, and the virtual cohomological dimension of the braid groups of S2 and RP2

Abstract

Let M be a surface, perhaps with boundary, and either compact, or with a finite number of points removed from the interior of the surface. We consider the inclusion i: F\n(M) -- Mn of the nth configuration space F\n(M) of M into the n-fold Cartesian product of M, as well as the induced homomorphism i\\#: P\n(M) -- (π\1(M))n, where P\n(M) is the n-string pure braid group of M. Both i and i\\# were studied initially by J.Birman who conjectured that Ker(i\\#) is equal to the normal closure of the Artin pure braid group P\n in P\n(M). The conjecture was later proved by C.Goldberg for compact surfaces without boundary different from the 2-sphere S2 and the projective plane RP2. In this paper, we prove the conjecture for S2 and RP2. In the case of RP2, we prove that Ker(i\\#) is equal to the commutator subgroup of P\n(RP2), we show that it may be decomposed in a manner similar to that of P\n(S2) as a direct sum of a torsion-free subgroup L\n and the finite cyclic group generated by the full twist braid, and we prove that L\n may be written as an iterated semi-direct product of free groups. Finally, we show that the groups B\n(S2) and P\n(S2) (resp. B\n(RP2) and P\n(RP2)) have finite virtual cohomological dimension equal to n-3 (resp. n-2), where B\n(M) denotes the full n-string braid group of M. This allows us to determine the virtual cohomological dimension of the mapping class groups of the mapping class groups of S2 and RP2 with marked points, which in the case of S2, reproves a result due to J.Harer.