Lefschetz manifold

Let M be a (2n)-dimensional smooth manifold. Each element :[\omega] \in H_{DR}^2 (M) of the second de Rham cohomology space of M induces a map :L_{[\omega]}: H_{DR} (M) \to H_{DR} (M), [\alpha] \mapsto [\omega \wedge \alpha] called the Lefschetz map of [\omega]. Letting L_{[\omega]}^i be the ith iteration of L_{[\omega]}, we have for each 0 \leq i \leq n a map :L_{[\omega]}^i : H_{DR}^{n-i}(M) \to H_{DR}^{n+i}(M). If M is compact and oriented, then Poincaré duality tells us that H_{DR}^{n-i}(M) and H_{DR}^{n+i}(M) are vector spaces of the same dimension, so in these cases it is natural to ask whether or not the various iterations of Lefschetz maps are isomorphisms. The Hard Lefschetz theorem states that this is the case for the symplectic form of a compact Kähler manifold. ==Definitions==

If :L_{[\omega]}^{n-1}: H_{DR}^1(M) \to H_{DR}^{2n-1} and :L_{[\omega]}^{n}: H_{DR}^0(M) \to H_{DR}^{2n} are isomorphisms, then [\omega] is a Lefschetz element, or Lefschetz class. If :L_{[\omega]}^i : H_{DR}^{n-i}(M) \to H_{DR}^{n+i}(M) is an isomorphism for all 0 \leq i \leq n, then [\omega] is a strong Lefschetz element, or a strong Lefschetz class. Let (M,\omega) be a 2n-dimensional symplectic manifold. Then it is orientable, but maybe not compact. One says that (M,\omega) is a Lefschetz manifold if [\omega] is a Lefschetz element, and (M,\omega) is a strong Lefschetz manifold if [\omega] is a strong Lefschetz element. ==Where to find Lefschetz manifolds==

The real manifold underlying any Kähler manifold is a symplectic manifold. The strong Lefschetz theorem tells us that it is also a strong Lefschetz manifold, and hence a Lefschetz manifold. Therefore we have the following chain of inclusions. {Kähler manifolds} \subset {strong Lefschetz manifolds} \subset{Lefschetz manifolds} \subset {symplectic manifolds} Chal Benson and Carolyn S. Gordon proved in 1988 that if a compact nilmanifold is a Lefschetz manifold, then it is diffeomorphic to a torus. The fact that there are nilmanifolds that are not diffeomorphic to a torus shows that there is some space between Kähler manifolds and symplectic manifolds, but the class of nilmanifolds fails to show any differences between Kähler manifolds, Lefschetz manifolds, and strong Lefschetz manifolds. Gordan and Benson conjectured that if a compact complete solvmanifold admits a Kähler structure, then it is diffeomorphic to a torus. This has been proved. Furthermore, many examples have been found of solvmanifolds that are strong Lefschetz but not Kähler, and solvmanifolds that are Lefschetz but not strong Lefschetz. Such examples were given by Takumi Yamada in 2002. ==Notes==