Let $X$ be an affine algebraic variety over an algebraically closed field $k$ of characteristic zero. Let $G$ be a reductive algebraic group acting on $X$. In this setting, there exists a categorical quotient variety $X / G$. Are there nice conditions (involving $X$ and/or $G$) that imply that $\mathrm{dim}(X / G) = \mathrm{dim}(X) - \mathrm{dim}(G)$? As pointed out in the comments, at a minimum one would have to require the action to be faithful.
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1 Answer
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A sufficient condition is that there should exist a closed orbit of maximal dimension (i.e. of dimension $\dim(G)$). Indeed, when it is the case, the stable locus is nonempty, and the image of the stable locus in $X/G$ is an open subset of $X/G$ of dimension $\dim(X)-\dim(G)$. This happens for instance if $G$ acts properly on $X$ (in this case all orbits are closed of maximal dimension).
It will not be possible to give a nice necessary and sufficient condition, because the property $\dim(X/G)=\dim(X)-\dim(G)$ is not a very natural one in this context. For example, it does not imply that the action is faithful : take $G=\mathbb{G}_m\times\mathbb{G}_m$ acting on $X=\mathbb{A}^2$ by $(s,t)\cdot(x,y)=(sx,sy)$.
answered Jul 24, 2012 at 20:40
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$\begingroup$ This criterion will certainly be useful; thank you. Can you give me a reference for the statements in your first paragraph? $\endgroup$ Commented Jul 25, 2012 at 16:41
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$\begingroup$ The reference I know is Mumford's GIT. More precisely : apply the theory of Chap.1, par.4 to $X$ and to the trivially $G$-linearized line bundle $\mathcal{O}_X$. First, considering the section $1\in H^0(X,\mathcal{O}_X)^G$, you see that all points of $X$ are semistable. The hypothesis about the closed orbit of maximal dimension shows that the stable locus is nonempty, by Amplification 1.11. Then you look at the categorical quotient provided by Thm. 1.10. Restricted to the stable locus, the quotient is geometric. For such a quotient, the dimensions add up (see the discussion before Prop 0.2). $\endgroup$ Commented Jul 25, 2012 at 19:55
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$\begingroup$ OK, thanks! I had been looking at Mumford but this directs my reading a lot more. $\endgroup$ Commented Jul 26, 2012 at 15:37
$\dim G =0$as an algebraic group.) Also, the question seems open-ended, with an indefinite number of correct answers. The literature on such group actions is wide-ranging and involves GIT too. $\endgroup$