# Quasi-homogeneity of the moduli space of stable maps to homogeneous   spaces

**Authors:** Christoph B\"arligea

arXiv: 1706.06452 · 2017-06-21

## TL;DR

This paper proves that certain moduli spaces of stable maps to homogeneous spaces are quasi-homogeneous under group actions, using quantum cohomology and combinatorial root theory, under minimal degree conditions.

## Contribution

It establishes quasi-homogeneity of moduli spaces for minimal degrees by explicitly constructing dense orbits, introducing a combinatorial theory of cascades of orthogonal roots.

## Key findings

- Moduli spaces are quasi-homogeneous under G action for minimal degrees.
- Constructed explicit morphisms with dense G-orbits in the moduli spaces.
- Developed a combinatorial theory of cascades of orthogonal roots.

## Abstract

Let $G$ be a connected, simply connected, simple, complex, linear algebraic group. Let $P$ be an arbitrary parabolic subgroup of $G$. Let $X=G/P$ be the $G$-homogeneous projective space attached to this situation. Let $d\in H_2(X)$ be a degree. Let $\overline{M}_{0,3}(X,d)$ be the (coarse) moduli space of three pointed genus zero stable maps to $X$ of degree $d$. We prove under reasonable assumptions on $d$ that $\overline{M}_{0,3}(X,d)$ is quasi-homogeneous under the action of $G$.   The essential assumption on $d$ is that $d$ is a minimal degree, i.e. that $d$ is a degree which is minimal with the property that $q^d$ occurs with non-zero coefficient in the quantum product $\sigma_u\star\sigma_v$ of two Schubert cycles $\sigma_u$ and $\sigma_v$, where $\star$ denotes the product in the (small) quantum cohomology ring $QH^*(X)$ attached to $X$. We prove our main result on quasi-homogeneity by constructing an explicit morphism which has a dense open $G$-orbit in $\overline{M}_{0,3}(X,d)$. To carry out the construction of this morphism, we develop a combinatorial theory of generalized cascades of orthogonal roots which is interesting in its own right.

## Full text

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## References

14 references — full list in the complete paper: https://tomesphere.com/paper/1706.06452/full.md

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Source: https://tomesphere.com/paper/1706.06452