Bounded Symmetric Domain
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, a Hermitian symmetric space is a
Hermitian manifold In mathematics, and more specifically in differential geometry, a Hermitian manifold is the complex analogue of a Riemannian manifold. More precisely, a Hermitian manifold is a complex manifold with a smoothly varying Hermitian inner product on ea ...
which at every point has an inversion symmetry preserving the Hermitian structure. First studied by
Élie Cartan Élie Joseph Cartan (; 9 April 1869 – 6 May 1951) was an influential French mathematician who did fundamental work in the theory of Lie groups, differential systems (coordinate-free geometric formulation of PDEs), and differential geometry. ...
, they form a natural generalization of the notion of
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from
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s to
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s. Every Hermitian symmetric space is a homogeneous space for its isometry group and has a unique decomposition as a product of irreducible spaces and a Euclidean space. The irreducible spaces arise in pairs as a non-compact space that, as
Borel Borel may refer to: People * Borel (author), 18th-century French playwright * Jacques Brunius, Borel (1906–1967), pseudonym of the French actor Jacques Henri Cottance * Émile Borel (1871 – 1956), a French mathematician known for his founding ...
showed, can be embedded as an open subspace of its compact dual space. Harish Chandra showed that each non-compact space can be realized as a bounded symmetric domain in a complex vector space. The simplest case involves the groups SU(2), SU(1,1) and their common complexification SL(2,C). In this case the non-compact space is the
unit disk In mathematics, the open unit disk (or disc) around ''P'' (where ''P'' is a given point in the plane), is the set of points whose distance from ''P'' is less than 1: :D_1(P) = \.\, The closed unit disk around ''P'' is the set of points whose di ...
, a homogeneous space for SU(1,1). It is a bounded domain in the complex plane C. The one-point compactification of C, the
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, is the dual space, a homogeneous space for SU(2) and SL(2,C). Irreducible compact Hermitian symmetric spaces are exactly the homogeneous spaces of simple compact Lie groups by maximal closed connected subgroups which contain a maximal torus and have center isomorphic to the circle group. There is a complete classification of irreducible spaces, with four classical series, studied by Cartan, and two exceptional cases; the classification can be deduced from Borel–de Siebenthal theory, which classifies closed connected subgroups containing a maximal torus. Hermitian symmetric spaces appear in the theory of
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s,
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,
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,
automorphic form In harmonic analysis and number theory, an automorphic form is a well-behaved function from a topological group ''G'' to the complex numbers (or complex vector space) which is invariant under the action of a discrete subgroup \Gamma \subset G of ...
s and
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s, in particular permitting the construction of the
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s of semisimple Lie groups.


Hermitian symmetric spaces of compact type


Definition

Let ''H'' be a connected compact semisimple Lie group, σ an automorphism of ''H'' of order 2 and ''H''σ the fixed point subgroup of σ. Let ''K'' be a closed subgroup of ''H'' lying between ''H''σ and its
identity component In mathematics, specifically group theory, the identity component of a group ''G'' refers to several closely related notions of the largest connected subgroup of ''G'' containing the identity element. In point set topology, the identity componen ...
. The compact homogeneous space ''H'' / ''K'' is called a symmetric space of compact type. The Lie algebra \mathfrak admits a decomposition :\displaystyle where \mathfrak, the Lie algebra of ''K'', is the +1 eigenspace of σ and \mathfrak the –1 eigenspace. If \mathfrak contains no simple summand of \mathfrak, the pair (\mathfrak, σ) is called an
orthogonal symmetric Lie algebra In mathematics, an orthogonal symmetric Lie algebra is a pair (\mathfrak, s) consisting of a real Lie algebra \mathfrak and an automorphism s of \mathfrak of order 2 such that the eigenspace \mathfrak of ''s'' corresponding to 1 (i.e., the set \m ...
of ''compact type''. Any inner product on \mathfrak, invariant under the
adjoint representation In mathematics, the adjoint representation (or adjoint action) of a Lie group ''G'' is a way of representing the elements of the group as linear transformations of the group's Lie algebra, considered as a vector space. For example, if ''G'' is G ...
and σ, induces a Riemannian structure on ''H'' / ''K'', with ''H'' acting by isometries. A canonical example is given by minus the
Killing form In mathematics, the Killing form, named after Wilhelm Killing, is a symmetric bilinear form that plays a basic role in the theories of Lie groups and Lie algebras. Cartan's criteria (criterion of solvability and criterion of semisimplicity) show ...
. Under such an inner product, \mathfrak and \mathfrak are orthogonal. ''H'' / ''K'' is then a Riemannian symmetric space of compact type. The symmetric space ''H'' / ''K'' is called a Hermitian symmetric space if it has an
almost complex structure In mathematics, an almost complex manifold is a smooth manifold equipped with a smooth linear complex structure on each tangent space. Every complex manifold is an almost complex manifold, but there are almost complex manifolds that are not complex ...
preserving the Riemannian metric. This is equivalent to the existence of a linear map ''J'' with ''J''2 = −''I'' on \mathfrak which preserves the inner product and commutes with the action of ''K''.


Symmetry and center of isotropy subgroup

If (\mathfrak,σ) is Hermitian, ''K'' has non-trivial center and the symmetry σ is inner, implemented by an element of the center of ''K''. In fact ''J'' lies in \mathfrak and exp ''tJ'' forms a one-parameter group in the center of ''K''. This follows because if ''A'', ''B'', ''C'', ''D'' lie in \mathfrak, then by the invariance of the inner product on \mathfrak :\displaystyle Replacing ''A'' and ''B'' by ''JA'' and ''JB'', it follows that :\displaystyle Define a linear map δ on \mathfrak by extending ''J'' to be 0 on \mathfrak. The last relation shows that δ is a derivation of \mathfrak. Since \mathfrak is semisimple, δ must be an inner derivation, so that :\displaystyle with ''T'' in \mathfrak and ''A'' in \mathfrak. Taking ''X'' in \mathfrak, it follows that ''A'' = 0 and ''T'' lies in the center of \mathfrak and hence that ''K'' is non-semisimple. The symmetry σ is implemented by ''z'' = exp π''T'' and the almost complex structure by exp π/2 ''T''. The innerness of σ implies that ''K'' contains a maximal torus of ''H'', so has maximal rank. On the other hand, the centralizer of the subgroup generated by the torus ''S'' of elements exp ''tT'' is connected, since if ''x'' is any element in ''K'' there is a maximal torus containing ''x'' and ''S'', which lies in the centralizer. On the other hand, it contains ''K'' since ''S'' is central in ''K'' and is contained in ''K'' since ''z'' lies in ''S''. So ''K'' is the centralizer of ''S'' and hence connected. In particular ''K'' contains the center of ''H''.


Irreducible decomposition

The symmetric space or the pair (\mathfrak, σ) is said to be ''irreducible'' if the adjoint action of \mathfrak (or equivalently the identity component of ''H''σ or ''K'') is irreducible on \mathfrak. This is equivalent to the maximality of \mathfrak as a subalgebra. In fact there is a one-one correspondence between intermediate subalgebras \mathfrak and ''K''-invariant subspaces \mathfrak_1 of \mathfrak given by :\displaystyle Any orthogonal symmetric algebra (\mathfrak, σ) of Hermitian type can be decomposed as an (orthogonal) direct sum of irreducible orthogonal symmetric algebras of Hermitian type. In fact \mathfrak can be written as a direct sum of simple algebras :\displaystyle each of which is left invariant by the automorphism σ and the complex structure ''J'', since they are both inner. The eigenspace decomposition of \mathfrak_1 coincides with its intersections with \mathfrak and \mathfrak. So the restriction of σ to \mathfrak_1 is irreducible. This decomposition of the orthogonal symmetric Lie algebra yields a direct product decomposition of the corresponding compact symmetric space ''H'' / ''K'' when ''H'' is simply connected. In this case the fixed point subgroup ''H''σ is automatically connected. For simply connected ''H'', the symmetric space ''H'' / ''K'' is the direct product of ''H''''i'' / ''K''''i'' with ''H''''i'' simply connected and simple. In the irreducible case, ''K'' is a maximal connected subgroup of ''H''. Since ''K'' acts irreducibly on \mathfrak (regarded as a complex space for the complex structure defined by ''J''), the center of ''K'' is a one-dimensional torus T, given by the operators exp ''tT''. Since each ''H'' is simply connected and ''K'' connected, the quotient ''H''/''K'' is simply connected.


Complex structure

if ''H'' / ''K'' is irreducible with ''K'' non-semisimple, the compact group ''H'' must be simple and ''K'' of maximal rank. From Borel-de Siebenthal theory, the involution σ is inner and ''K'' is the centralizer of its center, which is isomorphic to T. In particular ''K'' is connected. It follows that ''H'' / ''K'' is simply connected and there is a
parabolic subgroup In the theory of algebraic groups, a Borel subgroup of an algebraic group ''G'' is a maximal Zariski closed and connected solvable algebraic subgroup. For example, in the general linear group ''GLn'' (''n x n'' invertible matrices), the subgroup ...
''P'' in the
complexification In mathematics, the complexification of a vector space over the field of real numbers (a "real vector space") yields a vector space over the complex number field, obtained by formally extending the scaling of vectors by real numbers to include t ...
''G'' of ''H'' such that ''H'' / ''K'' = ''G'' / ''P''. In particular there is a complex structure on ''H'' / ''K'' and the action of ''H'' is holomorphic. Since any Hermitian symmetric space is a product of irreducible spaces, the same is true in general. At the
Lie algebra In mathematics, a Lie algebra (pronounced ) is a vector space \mathfrak g together with an Binary operation, operation called the Lie bracket, an Alternating multilinear map, alternating bilinear map \mathfrak g \times \mathfrak g \rightarrow ...
level, there is a symmetric decomposition :\mathfrak h = \mathfrak k\oplus\mathfrak m, where (\mathfrak m,J) is a real vector space with a complex structure ''J'', whose complex dimension is given in the table. Correspondingly, there is a
graded Lie algebra In mathematics, a graded Lie algebra is a Lie algebra endowed with a gradation which is compatible with the Lie bracket. In other words, a graded Lie algebra is a Lie algebra which is also a nonassociative graded algebra under the bracket oper ...
decomposition :\mathfrak g = \mathfrak_\oplus\mathfrak l\oplus\mathfrak_- where \mathfrak m\otimes\mathbb C= \mathfrak m_\oplus\mathfrak m_ is the decomposition into +''i'' and −''i'' eigenspaces of ''J'' and \mathfrak l=\mathfrak k\otimes\mathbb C. The Lie algebra of ''P'' is the semidirect product \mathfrak m^\oplus\mathfrak l. The complex Lie algebras \mathfrak_\pm are Abelian. Indeed, if ''U'' and ''V'' lie in \mathfrak_\pm, 'U'',''V''= ''J'' 'U'',''V''= 'JU'',''JV''= ''iU'',±''iV''= – 'U'',''V'' so the Lie bracket must vanish. The complex subspaces \mathfrak_\pm of \mathfrak_ are irreducible for the action of ''K'', since ''J'' commutes with ''K'' so that each is isomorphic to \mathfrak with complex structure ±''J''. Equivalently the centre T of ''K'' acts on \mathfrak_+ by the identity representation and on \mathfrak_- by its conjugate. The realization of ''H''/''K'' as a generalized flag variety ''G''/''P'' is obtained by taking ''G'' as in the table (the
complexification In mathematics, the complexification of a vector space over the field of real numbers (a "real vector space") yields a vector space over the complex number field, obtained by formally extending the scaling of vectors by real numbers to include t ...
of ''H'') and ''P'' to be the
parabolic subgroup In the theory of algebraic groups, a Borel subgroup of an algebraic group ''G'' is a maximal Zariski closed and connected solvable algebraic subgroup. For example, in the general linear group ''GLn'' (''n x n'' invertible matrices), the subgroup ...
equal to the semidirect product of ''L'', the complexification of ''K'', with the complex Abelian subgroup exp \mathfrak_+. (In the language of
algebraic groups In mathematics, an algebraic group is an algebraic variety endowed with a group structure which is compatible with its structure as an algebraic variety. Thus the study of algebraic groups belongs both to algebraic geometry and group theory. M ...
, ''L'' is the Levi factor of ''P''.)


Classification

Any Hermitian symmetric space of compact type is simply connected and can be written as a direct product of irreducible hermitian symmetric spaces ''H''''i'' / ''K''''i'' with ''H''''i'' simple, ''K''''i'' connected of maximal rank with center T. The irreducible ones are therefore exactly the non-semisimple cases classified by Borel–de Siebenthal theory. Accordingly, the irreducible compact Hermitian symmetric spaces ''H''/''K'' are classified as follows. In terms of the classification of compact Riemannian symmetric spaces, the Hermitian symmetric spaces are the four infinite series AIII, DIII, CI and BDI with ''p'' = 2 or ''q'' = 2, and two exceptional spaces, namely EIII and EVII.


Classical examples

The irreducible Hermitian symmetric spaces of compact type are all simply connected. The corresponding symmetry σ of the simply connected simple compact Lie group is inner, given by conjugation by the unique element ''S'' in ''Z''(''K'') / ''Z''(''H'') of period 2. For the classical groups, as in the table above, these symmetries are as follows: *AIII: S=\begin-\alpha I_p & 0\\ 0 & \alpha I_q\end in S(U(''p'')×U(''q'')), where α''p''+''q''=(−1)''p''. *DIII: ''S'' = ''iI'' in U(''n'') ⊂ SO(2''n''); this choice is equivalent to J_n=\begin0 &I_n \\ -I_n & 0\end. *CI: ''S''=''iI'' in U(''n'') ⊂ Sp(''n'') = Sp(''n'',C) ∩ U(2''n''); this choice is equivalent to ''J''''n''. *BDI: S=\beginI_p & 0\\ 0 & -I_2\end in SO(''p'')×SO(2). The maximal parabolic subgroup ''P'' can be described explicitly in these classical cases. For AIII :\displaystyle in SL(''p''+''q'',C). ''P''(''p'',''q'') is the stabilizer of a subspace of dimension ''p'' in C''p''+''q''. The other groups arise as fixed points of involutions. Let ''J'' be the ''n'' × ''n'' matrix with 1's on the antidiagonal and 0's elsewhere and set :\displaystyle Then Sp(''n'',C) is the fixed point subgroup of the involution θ(''g'') = ''A'' (''g''''t'')−1 ''A''−1 of SL(2''n'',C). SO(''n'',C) can be realised as the fixed points of ψ(''g'') = ''B'' (''g''''t'')−1 ''B''−1 in SL(''n'',C) where ''B'' = ''J''. These involutions leave invariant ''P''(''n'',''n'') in the cases DIII and CI and ''P''(''p'',2) in the case BDI. The corresponding parabolic subgroups ''P'' are obtained by taking the fixed points. The compact group ''H'' acts transitively on ''G'' / ''P'', so that ''G'' / ''P'' = ''H'' / ''K''.


Hermitian symmetric spaces of noncompact type


Definition

As with symmetric spaces in general, each compact Hermitian symmetric space ''H''/''K'' has a noncompact dual ''H''*/''K'' obtained by replacing ''H'' with the closed real Lie subgroup ''H''* of the complex Lie group ''G'' with Lie algebra :\mathfrak h^* = \mathfrak k \oplus i\mathfrak m\subset\mathfrak g.


Borel embedding

Whereas the natural map from ''H''/''K'' to ''G''/''P'' is an isomorphism, the natural map from ''H''*/''K'' to ''G''/''P'' is only an inclusion onto an open subset. This inclusion is called the Borel embedding after
Armand Borel Armand Borel (21 May 1923 – 11 August 2003) was a Swiss mathematician, born in La Chaux-de-Fonds, and was a permanent professor at the Institute for Advanced Study in Princeton, New Jersey, United States from 1957 to 1993. He worked in alg ...
. In fact ''P'' ∩ ''H'' = ''K'' = ''P'' ∩ ''H''*. The images of ''H'' and ''H''* have the same dimension so are open. Since the image of ''H'' is compact, so closed, it follows that ''H''/''K'' = ''G''/''P''.


Cartan decomposition

The polar decomposition in the complex linear group ''G'' implies the Cartan decomposition ''H''* = ''K'' ⋅ exp i\mathfrak in ''H''*. Moreover, given a maximal Abelian subalgebra \mathfrak in t, ''A'' = exp \mathfrak is a toral subgroup such that σ(''a'') = ''a''−1 on ''A''; and any two such \mathfrak's are conjugate by an element of ''K''. A similar statement holds for \mathfrak^*=i\mathfrak. Morevoer if ''A''* = exp \mathfrak^*, then :\displaystyle These results are special cases of the Cartan decomposition in any Riemannian symmetric space and its dual. The geodesics emanating from the origin in the homogeneous spaces can be identified with one parameter groups with generators in i\mathfrak or \mathfrak. Similar results hold for in the compact case: ''H''= ''K'' ⋅ exp i\mathfrak and ''H'' = ''KAK''. The properties of the
totally geodesic This is a glossary of some terms used in Riemannian geometry and metric geometry — it doesn't cover the terminology of differential topology. The following articles may also be useful; they either contain specialised vocabulary or provi ...
subspace ''A'' can be shown directly. ''A'' is closed because the closure of ''A'' is a toral subgroup satisfying σ(''a'') = ''a''−1, so its Lie algebra lies in \mathfrak and hence equals \mathfrak by maximality. ''A'' can be generated topologically by a single element exp ''X'', so \mathfrak is the centralizer of ''X'' in \mathfrak. In the ''K''-orbit of any element of \mathfrak there is an element ''Y'' such that (X,Ad ''k'' Y) is minimized at ''k'' = 1. Setting ''k'' = exp ''tT'' with ''T'' in \mathfrak, it follows that (''X'', 'T'',''Y'' = 0 and hence 'X'',''Y''= 0, so that ''Y'' must lie in \mathfrak. Thus \mathfrak is the union of the conjugates of \mathfrak. In particular some conjugate of ''X'' lies in any other choice of \mathfrak, which centralizes that conjugate; so by maximality the only possibilities are conjugates of \mathfrak. The decompositions :\displaystyle can be proved directly by applying the slice theorem for compact transformation groups to the action of ''K'' on ''H'' / ''K''. In fact the space ''H'' / ''K'' can be identified with :\displaystyle a closed submanifold of ''H'', and the Cartan decomposition follows by showing that ''M'' is the union of the ''kAk''−1 for ''k'' in ''K''. Since this union is the continuous image of ''K'' × ''A'', it is compact and connected. So it suffices to show that the union is open in ''M'' and for this it is enough to show each ''a'' in ''A'' has an open neighbourhood in this union. Now by computing derivatives at 0, the union contains an open neighbourhood of 1. If ''a'' is central the union is invariant under multiplication by ''a'', so contains an open neighbourhood of ''a''. If ''a'' is not central, write ''a'' = ''b''2 with ''b'' in ''A''. Then τ = Ad ''b'' − Ad ''b''−1 is a skew-adjoint operator on \mathfrak anticommuting with σ, which can be regarded as a Z2-grading operator σ on \mathfrak. By an
Euler–Poincaré characteristic In mathematics, and more specifically in algebraic topology and polyhedral combinatorics, the Euler characteristic (or Euler number, or Euler–Poincaré characteristic) is a topological invariant, a number that describes a topological space ...
argument it follows that the superdimension of \mathfrak coincides with the superdimension of the kernel of τ. In other words, :\displaystyle where \mathfrak_a and \mathfrak_a are the subspaces fixed by Ad ''a''. Let the orthogonal complement of \mathfrak_a in \mathfrak be \mathfrak_a^\perp. Computing derivatives, it follows that Ad ''e''''X'' (''a'' ''e''''Y''), where ''X'' lies in \mathfrak_a^\perp and ''Y'' in \mathfrak_a, is an open neighbourhood of ''a'' in the union. Here the terms ''a'' ''e''''Y'' lie in the union by the argument for central ''a'': indeed ''a'' is in the center of the identity component of the centralizer of ''a'' which is invariant under σ and contains ''A''. The dimension of \mathfrak is called the rank of the Hermitian symmetric space.


Strongly orthogonal roots

In the case of Hermitian symmetric spaces, Harish-Chandra gave a canonical choice for \mathfrak. This choice of \mathfrak is determined by taking a maximal torus ''T'' of ''H'' in ''K'' with Lie algebra \mathfrak. Since the symmetry σ is implemented by an element of ''T'' lying in the centre of ''H'', the root spaces \mathfrak_\alpha in \mathfrak are left invariant by σ. It acts as the identity on those contained in \mathfrak_ and minus the identity on those in \mathfrak_. The roots with root spaces in \mathfrak_ are called compact roots and those with root spaces in \mathfrak_ are called noncompact roots. (This terminology originates from the symmetric space of noncompact type.) If ''H'' is simple, the generator ''Z'' of the centre of ''K'' can be used to define a set of positive roots, according to the sign of α(''Z''). With this choice of roots \mathfrak_+ and \mathfrak_- are the direct sum of the root spaces \mathfrak_\alpha over positive and negative noncompact roots α. Root vectors ''E''α can be chosen so that :\displaystyle lie in \mathfrak. The simple roots α1, ...., α''n'' are the indecomposable positive roots. These can be numbered so that α''i'' vanishes on the center of \mathfrak for ''i'', whereas α1 does not. Thus α1 is the unique noncompact simple root and the other simple roots are compact. Any positive noncompact root then has the form β = α1 + ''c''2 α2 + ⋅⋅⋅ + ''c''''n'' α''n'' with non-negative coefficients ''c''''i''. These coefficients lead to a
lexicographic order In mathematics, the lexicographic or lexicographical order (also known as lexical order, or dictionary order) is a generalization of the alphabetical order of the dictionaries to sequences of ordered symbols or, more generally, of elements of a ...
on positive roots. The coefficient of α1 is always one because \mathfrak_- is irreducible for ''K'' so is spanned by vectors obtained by successively applying the lowering operators ''E''–α for simple compact roots α. Two roots α and β are said to be strongly orthogonal if ±α ±β are not roots or zero, written α ≐ β. The highest positive root ψ1 is noncompact. Take ψ2 to be the highest noncompact positive root strongly orthogonal to ψ1 (for the lexicographic order). Then continue in this way taking ψ''i'' + 1 to be the highest noncompact positive root strongly orthogonal to ψ1, ..., ψ''i'' until the process terminates. The corresponding vectors :\displaystyle lie in \mathfrak and commute by strong orthogonality. Their span \mathfrak is Harish-Chandra's canonical maximal Abelian subalgebra. (As Sugiura later showed, having fixed ''T'', the set of strongly orthogonal roots is uniquely determined up to applying an element in the Weyl group of ''K''.) Maximality can be checked by showing that if :\displaystyle for all ''i'', then ''c''α = 0 for all positive noncompact roots α different from the ψ''j'''s. This follows by showing inductively that if ''c''α ≠ 0, then α is strongly orthogonal to ψ1, ψ2, ... a contradiction. Indeed, the above relation shows ψ''i'' + α cannot be a root; and that if ψ''i'' – α is a root, then it would necessarily have the form β – ψ''i''. If ψ''i'' – α were negative, then α would be a higher positive root than ψ''i'', strongly orthogonal to the ψ''j'' with ''j'' < ''i'', which is not possible; similarly if β – ψ''i'' were positive.


Polysphere and polydisk theorem

Harish-Chandra's canonical choice of \mathfrak leads to a polydisk and polysphere theorem in ''H''*/''K'' and ''H''/''K''. This result reduces the geometry to products of the prototypic example involving SL(2,C), SU(1,1) and SU(2), namely the unit disk inside the Riemann sphere. In the case of ''H'' = SU(2) the symmetry σ is given by conjugation by the diagonal matrix with entries ±''i'' so that :\displaystyle The fixed point subgroup is the maximal torus ''T'', the diagonal matrices with entries ''e'' ±''it''. SU(2) acts on the Riemann sphere \mathbf^1 transitively by Möbius transformations and ''T'' is the stabilizer of 0. SL(2,C), the complexification of SU(2), also acts by Möbius transformations and the stabiliser of 0 is the subgroup ''B'' of lower triangular matrices. The noncompact subgroup SU(1,1) acts with precisely three orbits: the open unit disk , ''z'', < 1; the unit circle ''z'' = 1; and its exterior , ''z'', > 1. Thus :\displaystyle where ''B''+ and ''T''C denote the subgroups of upper triangular and diagonal matrices in SL(2,C). The middle term is the orbit of 0 under the upper unitriangular matrices :\displaystyle Now for each root ψ''i'' there is a homomorphism of π''i'' of SU(2) into ''H'' which is compatible with the symmetries. It extends uniquely to a homomorphism of SL(2,C) into ''G''. The images of the Lie algebras for different ψ''i'''s commute since they are strongly orthogonal. Thus there is a homomorphism π of the direct product SU(2)''r'' into ''H'' compatible with the symmetries. It extends to a homomorphism of SL(2,C)''r'' into ''G''. The kernel of π is contained in the center (±1)''r'' of SU(2)''r'' which is fixed pointwise by the symmetry. So the image of the center under π lies in ''K''. Thus there is an embedding of the polysphere (SU(2)/T)''r'' into ''H'' / ''K'' = ''G'' / ''P'' and the polysphere contains the polydisk (SU(1,1)/T)''r''. The polysphere and polydisk are the direct product of ''r'' copies of the Riemann sphere and the unit disk. By the Cartan decompositions in SU(2) and SU(1,1), the polysphere is the orbit of ''T''r''A'' in ''H'' / ''K'' and the polydisk is the orbit of ''T''''r''''A''*, where ''T''''r'' = π(T''r'') ⊆ ''K''. On the other hand, ''H'' = ''KAK'' and ''H''* = ''K'' ''A''* ''K''. Hence every element in the compact Hermitian symmetric space ''H'' / ''K'' is in the ''K''-orbit of a point in the polysphere; and every element in the image under the Borel embedding of the noncompact Hermitian symmetric space ''H''* / ''K'' is in the ''K''-orbit of a point in the polydisk.


Harish-Chandra embedding

''H''* / ''K'', the Hermitian symmetric space of noncompact type, lies in the image of \exp \mathfrak m_+, a dense open subset of ''H'' / ''K'' biholomorphic to \mathfrak m_+. The corresponding domain in \mathfrak m_+ is bounded. This is the Harish-Chandra embedding named after
Harish-Chandra Harish-Chandra Fellow of the Royal Society, FRS (11 October 1923 – 16 October 1983) was an Indian American mathematician and physicist who did fundamental work in representation theory, especially harmonic analysis on semisimple Lie groups. ...
. In fact Harish-Chandra showed the following properties of the space \mathbf=\exp (\mathfrak_+)\cdot K_ \cdot \exp(\mathfrak_-)=\exp (\mathfrak_+)\cdot P: # As a space, X is the direct product of the three factors. # X is open in ''G''. # X is dense in ''G''. # X contains ''H''*. # The closure of ''H''* / ''K'' in X / ''P'' = \exp \mathfrak_+ is compact. In fact M_\pm=\exp \mathfrak_\pm are complex Abelian groups normalised by ''K''C. Moreover, mathfrak_+,\mathfrak_-\subset \mathfrak_ since mathfrak,\mathfrak\subset \mathfrak. This implies ''P'' ∩ ''M''+ = . For if ''x'' = ''e''''X'' with ''X'' in \mathfrak_+ lies in ''P'', it must normalize ''M'' and hence \mathfrak_-. But if ''Y'' lies in \mathfrak_-, then :\displaystyle so that ''X'' commutes with \mathfrak_-. But if ''X'' commutes with every noncompact root space, it must be 0, so ''x'' = 1. It follows that the multiplication map μ on ''M''+ × ''P'' is injective so (1) follows. Similarly the derivative of μ at (''x'',''p'') is :\displaystyle which is injective, so (2) follows. For the special case ''H'' = SU(2), ''H''* = SU(1,1) and ''G'' = SL(2,C) the remaining assertions are consequences of the identification with the Riemann sphere, C and unit disk. They can be applied to the groups defined for each root ψ''i''. By the polysphere and polydisk theorem ''H''*/''K'', X/''P'' and ''H''/''K'' are the union of the ''K''-translates of the polydisk, C''r'' and the polysphere. So ''H''* lies in X, the closure of ''H''*/''K'' is compact in X/''P'', which is in turn dense in ''H''/''K''. Note that (2) and (3) are also consequences of the fact that the image of ''X'' in ''G''/''P'' is that of the big cell ''B''+''B'' in the Gauss decomposition of ''G''. Using results on the restricted root system of the symmetric spaces ''H''/''K'' and ''H''*/''K'', Hermann showed that the image of ''H''*/''K'' in \mathfrak_+ is a generalized unit disk. In fact it is the
convex set In geometry, a subset of a Euclidean space, or more generally an affine space over the reals, is convex if, given any two points in the subset, the subset contains the whole line segment that joins them. Equivalently, a convex set or a convex r ...
of ''X'' for which the
operator norm In mathematics, the operator norm measures the "size" of certain linear operators by assigning each a real number called its . Formally, it is a norm defined on the space of bounded linear operators between two given normed vector spaces. Introdu ...
of ad Im ''X'' is less than one.


Bounded symmetric domains

A bounded domain ''Ω'' in a complex vector space is said to be a bounded symmetric domain if for every ''x'' in ''Ω'', there is an involutive biholomorphism ''σ''''x'' of ''Ω'' for which ''x'' is an isolated fixed point. The Harish-Chandra embedding exhibits every Hermitian symmetric space of noncompact type ''H''* / ''K'' as a bounded symmetric domain. The biholomorphism group of ''H''* / ''K'' is equal to its isometry group ''H''*. Conversely every bounded symmetric domain arises in this way. Indeed, given a bounded symmetric domain ''Ω'', the
Bergman kernel In the mathematical study of several complex variables, the Bergman kernel, named after Stefan Bergman, is the reproducing kernel for the Hilbert space (RKHS) of all square integrable holomorphic functions on a domain ''D'' in C''n''. In deta ...
defines a
metric Metric or metrical may refer to: * Metric system, an internationally adopted decimal system of measurement * An adjective indicating relation to measurement in general, or a noun describing a specific type of measurement Mathematics In mathem ...
on ''Ω'', the
Bergman metric In differential geometry, the Bergman metric is a Hermitian metric that can be defined on certain types of complex manifold. It is so called because it is derived from the Bergman kernel, both of which are named after Stefan Bergman. Definition ...
, for which every biholomorphism is an isometry. This realizes ''Ω'' as a Hermitian symmetric space of noncompact type.


Classification

The irreducible bounded symmetric domains are called Cartan domains and are classified as follows.


Classical domains

In the classical cases (I–IV), the noncompact group can be realized by 2 × 2 block matrices :\displaystyle acting by generalized
Möbius transformation In geometry and complex analysis, a Möbius transformation of the complex plane is a rational function of the form f(z) = \frac of one complex variable ''z''; here the coefficients ''a'', ''b'', ''c'', ''d'' are complex numbers satisfying ''ad'' ...
s :\displaystyle The polydisk theorem takes the following concrete form in the classical cases: * Type I''pq'' (''p'' ≤ ''q''): for every ''p'' × ''q'' matrix ''M'' there are unitary matrices such that ''UMV'' is diagonal. In fact this follows from the
polar decomposition In mathematics, the polar decomposition of a square real or complex matrix A is a factorization of the form A = U P, where U is an orthogonal matrix and P is a positive semi-definite symmetric matrix (U is a unitary matrix and P is a positive semi ...
for ''p'' × ''p'' matrices. * Type III''n'': for every complex symmetric ''n'' × ''n'' matrix ''M'' there is a unitary matrix ''U'' such that ''UMU''''t'' is diagonal. This is proved by a classical argument of
Siegel Siegel (also Segal or Segel), is a German and Ashkenazi Jewish surname. it can be traced to 11th century Bavaria and was used by people who made wax seals for or sealed official documents (each such male being described as a ''Siegelbeamter''). ...
. Take ''V'' unitary so that ''V''*''M''*''MV'' is diagonal. Then ''V''''t''''MV'' is symmetric and its real and imaginary parts commute. Since they are real symmetric matrices they can be simultaneously diagonalized by a real orthogonal matrix ''W''. So ''UMU''''t'' is diagonal if ''U'' = ''WV''''t''. * Type II''n'': for every complex skew symmetric ''n'' × ''n'' matrix ''M'' there is a unitary matrix such that ''UMU''''t'' is made up of diagonal blocks \begin 0 & a\\ -a & 0\end and one zero if ''n'' is odd. As in Siegel's argument, this can be reduced to case where the real and imaginary parts of ''M'' commute. Any real skew-symmetric matrix can be reduced to the given
canonical form In mathematics and computer science, a canonical, normal, or standard form of a mathematical object is a standard way of presenting that object as a mathematical expression. Often, it is one which provides the simplest representation of an obje ...
by an orthogonal matrix and this can be done simultaneously for commuting matrices. * Type IV''n'': by a transformation in SO(''n'') × SO(2) any vector can be transformed so that all but the first two coordinates are non-zero.


Boundary components

The noncompact group ''H''* acts on the complex Hermitian symmetric space ''H''/''K'' = ''G''/''P'' with only finitely many orbits. The orbit structure is described in detail in . In particular the closure of the bounded domain ''H''*/''K'' has a unique closed orbit, which is the Shilov boundary of the domain. In general the orbits are unions of Hermitian symmetric spaces of lower dimension. The complex function theory of the domains, in particular the analogue of the
Cauchy integral formula In mathematics, Cauchy's integral formula, named after Augustin-Louis Cauchy, is a central statement in complex analysis. It expresses the fact that a holomorphic function defined on a disk is completely determined by its values on the boundary o ...
s, are described for the Cartan domains in . The closure of the bounded domain is the Baily–Borel compactification of ''H''*/''K''. The boundary structure can be described using
Cayley transform In mathematics, the Cayley transform, named after Arthur Cayley, is any of a cluster of related things. As originally described by , the Cayley transform is a mapping between skew-symmetric matrices and special orthogonal matrices. The transform ...
s. For each copy of SU(2) defined by one of the noncompact roots ψ''i'', there is a Cayley transform ''c''''i'' which as a Möbius transformation maps the unit disk onto the upper half plane. Given a subset ''I'' of indices of the strongly orthogonal family ψ1, ..., ψ''r'', the ''partial Cayley transform'' ''c''''I'' is defined as the product of the ''c''''i'''s with ''i'' in ''I'' in the product of the groups π''i''. Let ''G''(''I'') be the centralizer of this product in ''G'' and ''H''*(''I'') = ''H''* ∩ ''G''(''I''). Since σ leaves ''H''*(''I'') invariant, there is a corresponding Hermitian symmetric space ''M''''I'' ''H''*(''I'')/''H''*(''I'')∩''K'' ⊂ ''H''*/''K'' = ''M'' . The boundary component for the subset ''I'' is the union of the ''K''-translates of ''c''''I'' ''M''''I''. When ''I'' is the set of all indices, ''M''''I'' is a single point and the boundary component is the Shilov boundary. Moreover, ''M''''I'' is in the closure of ''M''''J'' if and only if ''I'' ⊇ ''J''.


Geometric properties

Every Hermitian symmetric space is a
Kähler manifold In mathematics and especially differential geometry, a Kähler manifold is a manifold with three mutually compatible structures: a complex structure, a Riemannian structure, and a symplectic structure. The concept was first studied by Jan Arnold ...
. They can be defined equivalently as Riemannian symmetric spaces with a parallel complex structure with respect to which the Riemannian metric is
Hermitian {{Short description, none Numerous things are named after the French mathematician Charles Hermite (1822–1901): Hermite * Cubic Hermite spline, a type of third-degree spline * Gauss–Hermite quadrature, an extension of Gaussian quadrature m ...
. The complex structure is automatically preserved by the isometry group ''H'' of the metric, and so any Hermitian symmetric space ''M'' is a homogeneous complex manifold. Some examples are
complex vector space In mathematics and physics, a vector space (also called a linear space) is a set whose elements, often called ''vectors'', may be added together and multiplied ("scaled") by numbers called ''scalars''. Scalars are often real numbers, but can ...
s and
complex projective space In mathematics, complex projective space is the projective space with respect to the field of complex numbers. By analogy, whereas the points of a real projective space label the lines through the origin of a real Euclidean space, the points of a ...
s, with their usual Hermitian metrics and
Fubini–Study metric In mathematics, the Fubini–Study metric is a Kähler metric on projective Hilbert space, that is, on a complex projective space CP''n'' endowed with a Hermitian form. This metric was originally described in 1904 and 1905 by Guido Fubini and Edua ...
s, and the complex
unit ball Unit may refer to: Arts and entertainment * UNIT, a fictional military organization in the science fiction television series ''Doctor Who'' * Unit of action, a discrete piece of action (or beat) in a theatrical presentation Music * ''Unit'' (alb ...
s with suitable metrics so that they become
complete Complete may refer to: Logic * Completeness (logic) * Completeness of a theory, the property of a theory that every formula in the theory's language or its negation is provable Mathematics * The completeness of the real numbers, which implies t ...
and Riemannian symmetric. The
compact Compact as used in politics may refer broadly to a pact or treaty; in more specific cases it may refer to: * Interstate compact * Blood compact, an ancient ritual of the Philippines * Compact government, a type of colonial rule utilized in British ...
Hermitian symmetric spaces are
projective varieties In algebraic geometry, a projective variety over an algebraically closed field ''k'' is a subset of some projective ''n''-space \mathbb^n over ''k'' that is the zero-locus of some finite family of homogeneous polynomials of ''n'' + 1 variables wi ...
, and admit a strictly larger
Lie group In mathematics, a Lie group (pronounced ) is a group that is also a differentiable manifold. A manifold is a space that locally resembles Euclidean space, whereas groups define the abstract concept of a binary operation along with the additio ...
''G'' of
biholomorphism In the mathematical theory of functions of one or more complex variables, and also in complex algebraic geometry, a biholomorphism or biholomorphic function is a bijective holomorphic function whose inverse is also holomorphic. Formal definit ...
s with respect to which they are homogeneous: in fact, they are
generalized flag manifold In mathematics, a generalized flag variety (or simply flag variety) is a homogeneous space whose points are flag (linear algebra), flags in a finite-dimensional vector space ''V'' over a field (mathematics), field F. When F is the real or complex nu ...
s, i.e., ''G'' is
semisimple In mathematics, semi-simplicity is a widespread concept in disciplines such as linear algebra, abstract algebra, representation theory, category theory, and algebraic geometry. A semi-simple object is one that can be decomposed into a sum of ''sim ...
and the stabilizer of a point is a
parabolic subgroup In the theory of algebraic groups, a Borel subgroup of an algebraic group ''G'' is a maximal Zariski closed and connected solvable algebraic subgroup. For example, in the general linear group ''GLn'' (''n x n'' invertible matrices), the subgroup ...
''P'' of ''G''. Among (complex) generalized flag manifolds ''G''/''P'', they are characterized as those for which the nilradical of the Lie algebra of ''P'' is abelian. Thus they are contained within the family of symmetric R-spaces which conversely comprises Hermitian symmetric spaces and their real forms. The non-compact Hermitian symmetric spaces can be realized as bounded domains in complex vector spaces.


Jordan algebras

Although the classical Hermitian symmetric spaces can be constructed by ad hoc methods,
Jordan triple system In algebra, a triple system (or ternar) is a vector space ''V'' over a field F together with a F-trilinear map : (\cdot,\cdot,\cdot) \colon V\times V \times V\to V. The most important examples are Lie triple systems and Jordan triple systems. The ...
s, or equivalently Jordan pairs, provide a uniform algebraic means of describing all the basic properties connected with a Hermitian symmetric space of compact type and its non-compact dual. This theory is described in detail in and and summarized in . The development is in the reverse order from that using the structure theory of compact Lie groups. It starting point is the Hermitian symmetric space of noncompact type realized as a bounded symmetric domain. It can be described in terms of a Jordan pair or hermitian
Jordan triple system In algebra, a triple system (or ternar) is a vector space ''V'' over a field F together with a F-trilinear map : (\cdot,\cdot,\cdot) \colon V\times V \times V\to V. The most important examples are Lie triple systems and Jordan triple systems. The ...
. This Jordan algebra structure can be used to reconstruct the dual Hermitian symmetric space of compact type, including in particular all the associated Lie algebras and Lie groups. The theory is easiest to describe when the irreducible compact Hermitian symmetric space is of tube type. In that case the space is determined by a simple real Lie algebra \mathfrak with negative definite Killing form. It must admit an action of SU(2) which only acts via the trivial and adjoint representation, both types occurring. Since \mathfrak is simple, this action is inner, so implemented by an inclusion of the Lie algebra of SU(2) in \mathfrak. The complexification of \mathfrak decomposes as a direct sum of three eigenspaces for the diagonal matrices in SU(2). It is a three-graded complex Lie algebra, with the Weyl group element of SU(2) providing the involution. Each of the ±1 eigenspaces has the structure of a unital complex Jordan algebra explicitly arising as the complexification of a Euclidean Jordan algebra. It can be identified with the multiplicity space of the adjoint representation of SU(2) in \mathfrak. The description of irreducible Hermitian symmetric spaces of tube type starts from a simple Euclidean Jordan algebra ''E''. It admits Jordan frames, i.e. sets of orthogonal minimal idempotents ''e''''1'', ..., ''e''''m''. Any two are related by an automorphism of ''E'', so that the integer ''m'' is an invariant called the rank of ''E''. Moreover, if ''A'' is the complexification of ''E'', it has a unitary structure group. It is a subgroup of GL(''A'') preserving the natural complex inner product on ''A''. Any element ''a'' in ''A'' has a polar decomposition with . The spectral norm is defined by , , a, , = sup α''i''. The associated
bounded symmetric domain In mathematics, a Hermitian symmetric space is a Hermitian manifold which at every point has an inversion symmetry preserving the Hermitian structure. First studied by Élie Cartan, they form a natural generalization of the notion of Riemannian ...
is just the open unit ball ''D'' in ''A''. There is a biholomorphism between ''D'' and the tube domain ''T'' = ''E'' + ''iC'' where ''C'' is the open self-dual convex cone of elements in ''E'' of the form with ''u'' an automorphism of ''E'' and α''i'' > 0. This gives two descriptions of the Hermitian symmetric space of noncompact type. There is a natural way of using
mutations In biology, a mutation is an alteration in the nucleic acid sequence of the genome of an organism, virus, or extrachromosomal DNA. Viral genomes contain either DNA or RNA. Mutations result from errors during DNA or viral replication, mi ...
of the Jordan algebra ''A'' to compactify the space ''A''. The compactification ''X'' is a complex manifold and the finite-dimensional Lie algebra \mathfrak of holomorphic vector fields on ''X'' can be determined explicitly. One parameter groups of biholomorphisms can be defined such that the corresponding holomorphic vector fields span \mathfrak. This includes the group of all complex Möbius transformations corresponding to matrices in SL(2,C). The subgroup SU(1,1) leaves invariant the unit ball and its closure. The subgroup SL(2,R) leaves invariant the tube domain and its closure. The usual Cayley transform and its inverse, mapping the unit disk in C to the upper half plane, establishes analogous maps between ''D'' and ''T''. The polydisk corresponds to the real and complex Jordan subalgebras generated by a fixed Jordan frame. It admits a transitive action of SU(2)''m'' and this action extends to ''X''. The group ''G'' generated by the one-parameter groups of biholomorphisms acts faithfully on \mathfrak. The subgroup generated by the identity component ''K'' of the unitary structure group and the operators in SU(2)''m''. It defines a compact Lie group ''H'' which acts transitively on ''X''. Thus ''H'' / ''K'' is the corresponding Hermitian symmetric space of compact type. The group ''G'' can be identified with the
complexification In mathematics, the complexification of a vector space over the field of real numbers (a "real vector space") yields a vector space over the complex number field, obtained by formally extending the scaling of vectors by real numbers to include t ...
of ''H''. The subgroup ''H''* leaving ''D'' invariant is a noncompact real form of ''G''. It acts transitively on ''D'' so that ''H''* / ''K'' is the dual Hermitian symmetric space of noncompact type. The inclusions ''D'' ⊂ ''A'' ⊂ ''X'' reproduce the Borel and Harish-Chandra embeddings. The classification of Hermitian symmetric spaces of tube type reduces to that of simple Euclidean Jordan algebras. These were classified by in terms of
Euclidean Hurwitz algebra In mathematics, Hurwitz's theorem is a theorem of Adolf Hurwitz (1859–1919), published posthumously in 1923, solving the Hurwitz problem for finite-dimensional unital algebra, unital real numbers, real non-associative algebras endowed with a posi ...
s, a special type of
composition algebra In mathematics, a composition algebra over a field is a not necessarily associative algebra over together with a nondegenerate quadratic form that satisfies :N(xy) = N(x)N(y) for all and in . A composition algebra includes an involution c ...
. In general a Hermitian symmetric space gives rise to a 3-graded Lie algebra with a period 2 conjugate linear automorphism switching the parts of degree ±1 and preserving the degree 0 part. This gives rise to the structure of a Jordan pair or hermitian
Jordan triple system In algebra, a triple system (or ternar) is a vector space ''V'' over a field F together with a F-trilinear map : (\cdot,\cdot,\cdot) \colon V\times V \times V\to V. The most important examples are Lie triple systems and Jordan triple systems. The ...
, to which extended the theory of Jordan algebras. All irreducible Hermitian symmetric spaces can be constructed uniformly within this framework. constructed the irreducible Hermitian symmetric space of non-tube type from a simple Euclidean Jordan algebra together with a period 2 automorphism. The −1 eigenspace of the automorphism has the structure of a Jordan pair, which can be deduced from that of the larger Jordan algebra. In the non-tube type case corresponding to a
Siegel domain In mathematics, a Siegel domain or Piatetski-Shapiro domain is a special open subset of complex affine space generalizing the Siegel upper half plane studied by . They were introduced by in his study of bounded homogeneous domains. Definitions A ...
of type II, there is no distinguished subgroup of real or complex Möbius transformations. For irreducible Hermitian symmetric spaces, tube type is characterized by the real dimension of the Shilov boundary being equal to the complex dimension of .


See also

* Invariant convex cone


Notes


References

* * * * * * * * * * * * The standard book on Riemannian symmetric spaces. * * * * * * * * * * * * . Chapter 8 contains a self-contained account of Hermitian symmetric spaces of compact type. *{{citation, last=Wolf, first= Joseph A., chapter=Fine structure of Hermitian symmetric spaces, title= Symmetric spaces (Short Courses, Washington University), pages= 271–357, publisher= Dekker, year= 1972, editor1-first=William, editor1-last=Boothby, editor2-first=Guido, editor2-last=Weiss, series=Pure and Applied Mathematics, volume=8. This contains a detailed account of Hermitian symmetric spaces of noncompact type. Differential geometry Complex manifolds Riemannian geometry Lie groups Homogeneous spaces