User:William Sarem/sandbox

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A function f defined on the domain D and with values in ${\displaystyle \mathbb {C} }$ is said to be holomorphic at a point ${\displaystyle z\in D}$ if it is complex-differentiable at this point, in the sense that there exists a complex linear map ${\displaystyle L:\mathbb {C} ^{n}\to \mathbb {C} }$ such that

${\displaystyle f(z+h)=f(z)+L(h)+o(\lVert h\rVert )}$

The function f is said to be holomorphic if it is holomorphic at all points of its domain of definition D.

If f is holomorphic, then all the partial maps :

${\displaystyle z\mapsto f(z_{1},\dots ,z_{i-1},z,z_{i+1},\dots ,z_{n})}$

are holomorphic as functions of one complex variable : we say that f is holomorphic in each variable separately. Conversely, if f is holomorphic in each variable separately, then f is in fact holomorphic : this is known as Hartog's theorem, or as Osgood's lemma under the additional hypothesis that f is continuous.

In mathematics, Matsushima's formula, introduced by Matsushima (1967), is a formula for the Betti numbers of a quotient of a symmetric space G/H by a discrete group, in terms of unitary representations of the group G. ^[1] The Matsushima–Murakami formula is a generalization giving dimensions of spaces of automorphic forms, introduced by Matsushima & Murakami (1968).^[2]

Let G be a Lie group, and K a connex compact subgroup of G. Denote ${\displaystyle {\mathcal {R}}_{G}}$ the set of all isomorphism classes of irreducible unitary representations ${\displaystyle \pi :G\to U(H_{\pi })}$, where ${\displaystyle H_{\pi }}$ is a complex separable Hilbert space and ${\displaystyle \pi }$ a group morphism. For every cocompact lattice ${\displaystyle \Gamma }$ of G, denote ${\displaystyle L^{2}(\Gamma \backslash G)}$ the Hilbert space of square-integrable complex-valued functions on ${\displaystyle \Gamma \backslash G}$, endowed with the hermitian product associated to the Haar measure on ${\displaystyle \Gamma \backslash G}$. Note that the existence of a cocompact lattice forces G to be unimodular. Then, there is a unitary representation ${\displaystyle \pi :G\to U(L^{2}(\Gamma \backslash G))}$, defined by the following formula:

${\displaystyle \forall g\in G,\forall f\in L^{2}(\Gamma \backslash G),\pi (g)(f)=f(\cdot g).}$

By ... theorem, the representation ${\displaystyle \pi }$ can be decomposed into irreducible unitary representations, each one appearing at most a finite number of times:

${\displaystyle L^{2}(\Gamma \backslash G)={\widetilde {\bigoplus _{\pi \in R_{G}}}}m_{\pi }(\Gamma )H_{\pi }}$

In this decomposition, the sum is a Hilbertian direct sum, and at most a countable number of terms are nonzero, because ${\displaystyle L^{2}(\Gamma \backslash G)}$ is separable. It is a part of the theorem that all multiplicities ${\displaystyle m_{\pi }(\Gamma )}$ are finite.

In this context, the Matsushima formula is the following decomposition of the complex De Rham cohomology of the manifold ${\displaystyle \Gamma \backslash G/K}$:

${\displaystyle H_{dR}^{i}(\Gamma \backslash G/K,\mathbb {C} )\simeq \bigoplus _{\pi \in {\mathcal {R}}_{G}}m_{\pi }(\Gamma )H^{i}({\mathfrak {g}},{\mathfrak {k}},H_{\pi }^{\infty })}$

In this formula the multiplicities ${\displaystyle m_{\pi }(\Gamma )}$ are exactly the one appearing in the previous decomposition of ${\displaystyle L^{2}(\Gamma \backslash G)}$ into irreducibles representations. The symbols ${\displaystyle {\mathfrak {g}},{\mathfrak {k}}}$ respectively denotes the Lie algebras associated with G and K, and ${\displaystyle H_{\pi }^{\infty }\subset H_{\pi }}$ is the subspace of ${\displaystyle C^{\infty }}$-vectors for the representation ${\displaystyle \pi }$, which is also a ${\displaystyle {\mathfrak {g}}}$-module. Finally, ${\displaystyle H^{*}({\mathfrak {g}},{\mathfrak {k}},H_{\pi }^{\infty })}$ is the cohomology of the Chevalley–Eilenberg complex associated to ${\displaystyle {\mathfrak {g}},{\mathfrak {k}},H_{\pi }^{\infty }}$. Remark that, since the compact manifold ${\displaystyle \Gamma \backslash G/K}$ has finite cohomology spaces, the sum on the right must have finitely many non-zero terms, and thus only a finite number of irreducible sub-representations of ${\displaystyle \pi :G\to U(L^{2}(\Gamma \backslash G))}$ have non-vanishing cohomology.