Let $M$ be a toric manifold. I'm not sure what conditions on $M$ are required, but one can assume, if needed, that it is compact, smooth, etc. We consider $M$ as a quotient given by the momentum map $P$ of the action of a torus $\mathbb{K} \subset (S^1)^n$ of dimension $k$: $$M = P^{-1}(p) \ / \ \mathbb{K}, \ \ p \text{ regular value of } P : \mathbb{C}^n \to \text{Lie}(\mathbb{K})^*.$$
I am interested in the cohomology $$H^*(M,\mathbb{C})$$ of $M$ with complex coefficients. More precisely, one can show that it is naturally ismorphic to the following quotient $$H^*(M,\mathbb{C}) \simeq \mathbb{C}[u_1,...,u_n] \ / \ (I + J),$$ where:
- $I$ is the ideal of polynomials which vanish on $\mathbb{C}^k = \text{Lie}(\mathbb{K}) \otimes \mathbb{C} \subset \mathbb{C}^n = \mathbb{R}^n \otimes \mathbb{C}$;
- J is the ideal generated by monomials $u_1^{m_1}...u_n^{m_n}$ such that $m = (m_1,...,m_n)$, considered as linear functions on $\mathbb{R}^{n*}$, assume strictly positive values on the polyhedron image of the momentum map of the action of $(S^1)^n \ / \ \mathbb{K}$ on $M$.
My question is: is this algebra a finite dimensional vector space over $\mathbb{C}$ ? If yes, how to prove this ?
