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Hallo,

Let $G$ be a semi-simple, compact Lie Group. Consider its complexification $G_{\mathbb{C}}$. Does there exist a Kähler structure on $G_{\mathbb{C}}$ which is $G$-invariant (maybe in a neighbourhood of $G$ in $G_{\mathbb{C}}$)?

hapchiu

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Yes, such a Kähler form always exists: Embed $G$ as a matrix group in $\mathrm{SU}(n)$ for some $n$ and then let $G_\mathbb{C}\subset \mathrm{SL}(n,\mathbb{C})\subset M_n(\mathbb{C})$ be the complexification. Choose a Kähler form on this latter vector space, pull it back to $G_\mathbb{C}$ and then, using the compactness of $G$, average its pullbacks under left and right multiplications. This will yield a Kähler form on $G_\mathbb{C}$ that is $G$-invariant.

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Is there any reference where I can see how the proof is done? – hapchiu Dec 2 at 8:27
what do you mean by average its pullbacks under left and right multiplications if $G$ is compact??? – hapchiu Dec 2 at 8:59
@hapchiu: It's a standard technique. If you have a compact Lie group $H$ acting on the left as biholomorphic transformations on a Kähler manifold $M$, then, letting $dh$ be Haar measure on $H$ and $\Omega$ be a Kähler form on $M$, one can construct an $H$-invariant Kähler form on $M$ by averaging: $$\bar\Omega = \int_H L_h^*(\Omega)\ dh\ ,$$ where $L_h:M\to M$ is left action by $h\in H$. In your case, $M=G_\mathbb{C}$ and $H = G\times G$, with $L_{(g_1,g_2)}(g) = g_1g{g_2}^{-1}$. – Robert Bryant Dec 2 at 13:21

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