Cohomological rigidity of manifolds defined by 3-dimensional polytopes

Abstract: Abstract. A family of closed manifolds is called cohomologically rigid if a cohomology ring isomorphism implies a diffeomorphism for any two manifolds in the family. We establish cohomological rigidity for large families of 3-dimensional and 6-dimensional manifolds defined by 3-dimensional polytopes.We consider the class P of 3-dimensional combinatorial simple polytopes P , different from a tetrahedron, whose facets do not form 3-and 4-belts. This class includes mathematical fullerenes, i. e. simple 3-polytope… Show more

“…Now we consider the problem of existence of nontrivial Massey products in H * (Z P ) for Pogorelov polytopes P . As noted in[6, Proposition 4.8], triple Massey products of 3-dimensional cohomology classes (3.1) are trivial for simple polytopes P without 4-belts, in particular, for Pogorelov polytopes. In this paper we prove the following: For any Pogorelov polytope P , there exists a nontrivial triple Massey product α…”

“…This class consists of combinatorial 3-dimensional simple polytopes which do not have 3-belts and 4-belts of facets. It is known that the Pogorelov class consists precisely of combinatorial 3-polytopes which admit a right-angled realization in Lobachevsky space L 3 , and such a realization is unique up to isometry (see [4], [5], [6]). There is a family of hyperbolic 3-manifolds associated with Pogorelov polytopes, known as hyperbolic manifolds of Löbell type (see [7]).…”

Massey Products in the Cohomology of the Moment-Angle Manifolds Corresponding to Pogorelov Polytopes

“…Now we consider the problem of existence of nontrivial Massey products in H * (Z P ) for Pogorelov polytopes P . As noted in[6, Proposition 4.8], triple Massey products of 3-dimensional cohomology classes (3.1) are trivial for simple polytopes P without 4-belts, in particular, for Pogorelov polytopes. In this paper we prove the following: For any Pogorelov polytope P , there exists a nontrivial triple Massey product α…”

“…This class consists of combinatorial 3-dimensional simple polytopes which do not have 3-belts and 4-belts of facets. It is known that the Pogorelov class consists precisely of combinatorial 3-polytopes which admit a right-angled realization in Lobachevsky space L 3 , and such a realization is unique up to isometry (see [4], [5], [6]). There is a family of hyperbolic 3-manifolds associated with Pogorelov polytopes, known as hyperbolic manifolds of Löbell type (see [7]).…”

Massey Products in the Cohomology of the Moment-Angle Manifolds Corresponding to Pogorelov Polytopes

“…Since the "C-rigidity" requires the existence of quasitoric manifold over a given polytope, there is no canonical way to define the C-rigidity of such polytopes. Thus there has been confusion; some literatures such as [7] define that such polytope is not C-rigid, but some literatures such as [3] define that such polytopes are C-rigid as their conventions. However, it does not matter because the Crigidity of P should be considered only when P supports a quasitoric manifold.…”

“…In [5], the first named author found the counterexample of the reverse implication of (1); there is a 3-dimensional B-rigid simple polytope with 11 facets which is not A-rigid. However, the reverse implication of (2) has been open (see the remark in Section 3 of [3]).…”

Example of C-rigid polytopes which are not B-rigid

“…The isometry group of the Al-Jubouri and the Seifert-Weber manifolds was found in the papers [4] and [15] respectively. Further generalization of tetrahedral manifolds known as Löbell type manifolds was done in series of papers ( [20], [21], [3], [5], [6], [16], [2]). The arithmetic properties of the tetrahedral manifolds investigated in [14].…”

Mirror symmetries of hyperbolic tetrahedral manifolds