Difference between revisions of "Symplectic homogeneous space"
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− | + | A [[Symplectic manifold|symplectic manifold]] $ ( M, \omega ) $ | |
+ | together with a transitive Lie group $ G $ | ||
+ | of automorphisms of $ M $. | ||
+ | The elements of the Lie algebra $ \mathfrak g $ | ||
+ | of $ G $ | ||
+ | can be regarded as symplectic vector fields on $ M $, | ||
+ | i.e. fields $ X $ | ||
+ | that preserve the symplectic $ 2 $- | ||
+ | form $ \omega $: | ||
− | + | $$ | |
+ | X \cdot \omega = di _ {X} \omega = 0, | ||
+ | $$ | ||
− | where | + | where the dot denotes the Lie derivative, $ i _ {X} $ |
+ | is the operation of interior multiplication by $ X $ | ||
+ | and $ d $ | ||
+ | is the exterior differential. A symplectic homogeneous space is said to be strictly symplectic if all fields $ X \in \mathfrak g $ | ||
+ | are Hamiltonian, i.e. $ i _ {X} \omega = dH _ {X} $, | ||
+ | where $ H _ {X} $ | ||
+ | is a function on $ M $( | ||
+ | the Hamiltonian of $ X $) | ||
+ | that can be chosen in such a way that the mapping $ X \mapsto H _ {X} $ | ||
+ | is a homomorphism from the Lie algebra $ \mathfrak g $ | ||
+ | to the Lie algebra of functions on $ M $ | ||
+ | with respect to the Poisson bracket. An example of a strictly-symplectic homogeneous space is the orbit $ M _ \alpha = ( \mathop{\rm Ad} ^ {*} G) \alpha $ | ||
+ | of the Lie group $ G $ | ||
+ | relative to its co-adjoint representation $ \mathop{\rm Ad} ^ {*} G $ | ||
+ | in the space $ \mathfrak g ^ {*} $ | ||
+ | of linear forms on $ \mathfrak g $, | ||
+ | passing through an arbitrary point $ \alpha \in \mathfrak g ^ {*} $. | ||
+ | The invariant symplectic $ 2 $- | ||
+ | form $ \omega $ | ||
+ | on $ M _ \alpha $ | ||
+ | is given by the formula | ||
− | + | $$ | |
+ | \omega ( X _ \beta , Y _ \beta ) = \ | ||
+ | d \beta ( X, Y) \equiv \beta ([ X, Y]), | ||
+ | $$ | ||
− | + | where $ X _ \beta $, | |
+ | $ Y _ \beta $ | ||
+ | are the values of the vector fields $ X, Y \in \mathfrak g $ | ||
+ | at $ \beta \in M _ \alpha $. | ||
+ | The field $ X \in \mathfrak g $ | ||
+ | has Hamiltonian $ H _ {X} ( \beta ) = \beta ( X) $. | ||
− | + | For an arbitrary strictly-symplectic homogeneous space $ ( M, \omega , G) $ | |
+ | there is the $ G $- | ||
+ | equivariant moment mapping | ||
− | + | $$ | |
+ | \mu : M \rightarrow \mathfrak g ^ {*} ,\ \ | ||
+ | x \mapsto \mu _ {x} ,\ \ | ||
+ | \mu _ {x} ( X) = H _ {X} ( x), | ||
+ | $$ | ||
− | + | which maps $ M $ | |
+ | onto the orbit $ \mu ( M) $ | ||
+ | of $ G $ | ||
+ | in $ \mathfrak g ^ {*} $ | ||
+ | and is a local isomorphism of symplectic manifolds. Thus, every strictly-symplectic homogeneous space of $ G $ | ||
+ | is a covering over an orbit of $ G $ | ||
+ | in the co-adjoint representation. | ||
− | A symplectic group space is a special type of symplectic homogeneous space. It consists of a Lie group together with a left-invariant symplectic form | + | The simply-connected symplectic homogeneous spaces with a simply-connected, but not necessarily effectively-acting automorphism group $ G $ |
+ | are in one-to-one correspondence with the orbits of the natural action of $ G $ | ||
+ | on the space $ Z ^ {2} ( \mathfrak g ) $ | ||
+ | of closed $ 2 $- | ||
+ | forms on its Lie algebra $ \mathfrak g $. | ||
+ | The correspondence is defined in the following way. The kernel $ \mathfrak K ^ \sigma $ | ||
+ | of any $ 2 $- | ||
+ | form $ \sigma \in Z ^ {2} ( \mathfrak g ) $ | ||
+ | is a subalgebra of $ \mathfrak g $. | ||
+ | The connected subgroup $ K ^ \sigma $ | ||
+ | of the Lie group $ G $ | ||
+ | corresponding to $ \mathfrak K ^ \sigma $ | ||
+ | is closed and defines a simply-connected homogeneous space $ M ^ \sigma = G/K ^ \sigma $. | ||
+ | The form $ \sigma $ | ||
+ | determines a non-degenerate $ 2 $- | ||
+ | form on the tangent space $ T _ {O} M ^ \sigma \simeq \mathfrak g / \mathfrak K ^ \sigma $ | ||
+ | at a point $ O = eK ^ \sigma $ | ||
+ | of the manifold $ M ^ \sigma $, | ||
+ | which extends to a $ G $- | ||
+ | invariant symplectic form $ \omega ^ \sigma $ | ||
+ | on $ M ^ \sigma $. | ||
+ | Thus, to the form $ \sigma $ | ||
+ | one assigns the simply-connected symplectic homogeneous space $ ( M ^ \sigma , \omega ^ \sigma ) $. | ||
+ | If $ \mathfrak K ^ \sigma $ | ||
+ | contains no ideals of $ \mathfrak g $, | ||
+ | then the action of $ G $ | ||
+ | on $ M ^ \sigma $ | ||
+ | is locally effective. Two symplectic homogeneous spaces $ M ^ \sigma $ | ||
+ | and $ M ^ {\sigma ^ \prime } $ | ||
+ | are isomorphic if and only if the forms $ \sigma $, | ||
+ | $ \sigma ^ \prime $ | ||
+ | belong to the same orbit of $ G $ | ||
+ | on $ Z ^ {2} ( \mathfrak g ) $. | ||
+ | For an exact $ 2 $- | ||
+ | form $ \sigma = d \alpha $, | ||
+ | the symplectic homogeneous space $ M ^ \sigma $ | ||
+ | is identified with the universal covering of the symplectic homogeneous space $ M _ \alpha $, | ||
+ | which is the orbit of a point $ \alpha $ | ||
+ | in the co-adjoint representation. If $ [ \mathfrak g , \mathfrak g ] = \mathfrak g $, | ||
+ | then the orbit $ G \sigma $ | ||
+ | of any point $ \sigma \in Z ^ {2} ( \mathfrak g ) $ | ||
+ | is canonically provided with the structure of a symplectic homogeneous space, and any symplectic homogeneous space of a simply-connected group $ G $ | ||
+ | is isomorphic to the covering over one of these orbits. In particular, $ M ^ \sigma $ | ||
+ | is the universal covering of $ G \sigma $. | ||
+ | |||
+ | Let $ ( M, \omega ) $ | ||
+ | be a compact symplectic homogeneous space of a simply-connected connected group $ G $ | ||
+ | whose action is locally effective. Then $ G $ | ||
+ | is the direct product of a semi-simple compact group $ S $ | ||
+ | and a solvable group $ R $ | ||
+ | isomorphic to the semi-direct product of an Abelian subgroup and an Abelian normal subgroup, and the symplectic homogeneous space $ ( M, \omega ) $ | ||
+ | decomposes into the direct product of symplectic homogeneous spaces with automorphism groups $ S $ | ||
+ | and $ R $, | ||
+ | respectively. | ||
+ | |||
+ | A symplectic group space is a special type of symplectic homogeneous space. It consists of a Lie group together with a left-invariant symplectic form $ \omega $. | ||
+ | It is known that for a Lie group admitting a left-invariant symplectic form, reductivity implies commutativity, and unimodularity implies solvability. All such groups of dimension $ \leq 4 $ | ||
+ | are solvable, but from dimension 6 onwards there are unsolvable symplectic group spaces [[#References|[3]]]. | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> A.A. Kirillov, "Elements of the theory of representations" , Springer (1976) (Translated from Russian)</TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> V. Guillemin, S. Sternberg, "Geometric asymptotics" , Amer. Math. Soc. (1977)</TD></TR><TR><TD valign="top">[3]</TD> <TD valign="top"> B.-Y. Chu, "Symplectic homogeneous spaces" ''Trans. Amer. Math. Soc.'' , '''197''' (1974) pp. 145–159</TD></TR><TR><TD valign="top">[4]</TD> <TD valign="top"> Ph.B. Zwart, W.M. Boothby, "On compact, homogeneous symplectic manifolds" ''Ann. Inst. Fourier'' , '''30''' : 1 (1980) pp. 129–157</TD></TR><TR><TD valign="top">[5]</TD> <TD valign="top"> N.E. Hurt, "Geometric quantization in action" , Reidel (1983)</TD></TR><TR><TD valign="top">[6]</TD> <TD valign="top"> D.V. Alekseevskii, A.M. Vinogradov, V.V. Lychagin, "The principal ideas and methods of differential geometry" , ''Encycl. Math. Sci.'' , '''28''' , Springer (Forthcoming) pp. Chapt. 4, Sect. 5 (Translated from Russian)</TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> A.A. Kirillov, "Elements of the theory of representations" , Springer (1976) (Translated from Russian)</TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> V. Guillemin, S. Sternberg, "Geometric asymptotics" , Amer. Math. Soc. (1977)</TD></TR><TR><TD valign="top">[3]</TD> <TD valign="top"> B.-Y. Chu, "Symplectic homogeneous spaces" ''Trans. Amer. Math. Soc.'' , '''197''' (1974) pp. 145–159</TD></TR><TR><TD valign="top">[4]</TD> <TD valign="top"> Ph.B. Zwart, W.M. Boothby, "On compact, homogeneous symplectic manifolds" ''Ann. Inst. Fourier'' , '''30''' : 1 (1980) pp. 129–157</TD></TR><TR><TD valign="top">[5]</TD> <TD valign="top"> N.E. Hurt, "Geometric quantization in action" , Reidel (1983)</TD></TR><TR><TD valign="top">[6]</TD> <TD valign="top"> D.V. Alekseevskii, A.M. Vinogradov, V.V. Lychagin, "The principal ideas and methods of differential geometry" , ''Encycl. Math. Sci.'' , '''28''' , Springer (Forthcoming) pp. Chapt. 4, Sect. 5 (Translated from Russian)</TD></TR></table> | ||
− | |||
− | |||
====Comments==== | ====Comments==== | ||
See [[Lie differentiation|Lie differentiation]] for the definitions of Lie derivative and interior multiplication. | See [[Lie differentiation|Lie differentiation]] for the definitions of Lie derivative and interior multiplication. |
Latest revision as of 08:24, 6 June 2020
A symplectic manifold $ ( M, \omega ) $
together with a transitive Lie group $ G $
of automorphisms of $ M $.
The elements of the Lie algebra $ \mathfrak g $
of $ G $
can be regarded as symplectic vector fields on $ M $,
i.e. fields $ X $
that preserve the symplectic $ 2 $-
form $ \omega $:
$$ X \cdot \omega = di _ {X} \omega = 0, $$
where the dot denotes the Lie derivative, $ i _ {X} $ is the operation of interior multiplication by $ X $ and $ d $ is the exterior differential. A symplectic homogeneous space is said to be strictly symplectic if all fields $ X \in \mathfrak g $ are Hamiltonian, i.e. $ i _ {X} \omega = dH _ {X} $, where $ H _ {X} $ is a function on $ M $( the Hamiltonian of $ X $) that can be chosen in such a way that the mapping $ X \mapsto H _ {X} $ is a homomorphism from the Lie algebra $ \mathfrak g $ to the Lie algebra of functions on $ M $ with respect to the Poisson bracket. An example of a strictly-symplectic homogeneous space is the orbit $ M _ \alpha = ( \mathop{\rm Ad} ^ {*} G) \alpha $ of the Lie group $ G $ relative to its co-adjoint representation $ \mathop{\rm Ad} ^ {*} G $ in the space $ \mathfrak g ^ {*} $ of linear forms on $ \mathfrak g $, passing through an arbitrary point $ \alpha \in \mathfrak g ^ {*} $. The invariant symplectic $ 2 $- form $ \omega $ on $ M _ \alpha $ is given by the formula
$$ \omega ( X _ \beta , Y _ \beta ) = \ d \beta ( X, Y) \equiv \beta ([ X, Y]), $$
where $ X _ \beta $, $ Y _ \beta $ are the values of the vector fields $ X, Y \in \mathfrak g $ at $ \beta \in M _ \alpha $. The field $ X \in \mathfrak g $ has Hamiltonian $ H _ {X} ( \beta ) = \beta ( X) $.
For an arbitrary strictly-symplectic homogeneous space $ ( M, \omega , G) $ there is the $ G $- equivariant moment mapping
$$ \mu : M \rightarrow \mathfrak g ^ {*} ,\ \ x \mapsto \mu _ {x} ,\ \ \mu _ {x} ( X) = H _ {X} ( x), $$
which maps $ M $ onto the orbit $ \mu ( M) $ of $ G $ in $ \mathfrak g ^ {*} $ and is a local isomorphism of symplectic manifolds. Thus, every strictly-symplectic homogeneous space of $ G $ is a covering over an orbit of $ G $ in the co-adjoint representation.
The simply-connected symplectic homogeneous spaces with a simply-connected, but not necessarily effectively-acting automorphism group $ G $ are in one-to-one correspondence with the orbits of the natural action of $ G $ on the space $ Z ^ {2} ( \mathfrak g ) $ of closed $ 2 $- forms on its Lie algebra $ \mathfrak g $. The correspondence is defined in the following way. The kernel $ \mathfrak K ^ \sigma $ of any $ 2 $- form $ \sigma \in Z ^ {2} ( \mathfrak g ) $ is a subalgebra of $ \mathfrak g $. The connected subgroup $ K ^ \sigma $ of the Lie group $ G $ corresponding to $ \mathfrak K ^ \sigma $ is closed and defines a simply-connected homogeneous space $ M ^ \sigma = G/K ^ \sigma $. The form $ \sigma $ determines a non-degenerate $ 2 $- form on the tangent space $ T _ {O} M ^ \sigma \simeq \mathfrak g / \mathfrak K ^ \sigma $ at a point $ O = eK ^ \sigma $ of the manifold $ M ^ \sigma $, which extends to a $ G $- invariant symplectic form $ \omega ^ \sigma $ on $ M ^ \sigma $. Thus, to the form $ \sigma $ one assigns the simply-connected symplectic homogeneous space $ ( M ^ \sigma , \omega ^ \sigma ) $. If $ \mathfrak K ^ \sigma $ contains no ideals of $ \mathfrak g $, then the action of $ G $ on $ M ^ \sigma $ is locally effective. Two symplectic homogeneous spaces $ M ^ \sigma $ and $ M ^ {\sigma ^ \prime } $ are isomorphic if and only if the forms $ \sigma $, $ \sigma ^ \prime $ belong to the same orbit of $ G $ on $ Z ^ {2} ( \mathfrak g ) $. For an exact $ 2 $- form $ \sigma = d \alpha $, the symplectic homogeneous space $ M ^ \sigma $ is identified with the universal covering of the symplectic homogeneous space $ M _ \alpha $, which is the orbit of a point $ \alpha $ in the co-adjoint representation. If $ [ \mathfrak g , \mathfrak g ] = \mathfrak g $, then the orbit $ G \sigma $ of any point $ \sigma \in Z ^ {2} ( \mathfrak g ) $ is canonically provided with the structure of a symplectic homogeneous space, and any symplectic homogeneous space of a simply-connected group $ G $ is isomorphic to the covering over one of these orbits. In particular, $ M ^ \sigma $ is the universal covering of $ G \sigma $.
Let $ ( M, \omega ) $ be a compact symplectic homogeneous space of a simply-connected connected group $ G $ whose action is locally effective. Then $ G $ is the direct product of a semi-simple compact group $ S $ and a solvable group $ R $ isomorphic to the semi-direct product of an Abelian subgroup and an Abelian normal subgroup, and the symplectic homogeneous space $ ( M, \omega ) $ decomposes into the direct product of symplectic homogeneous spaces with automorphism groups $ S $ and $ R $, respectively.
A symplectic group space is a special type of symplectic homogeneous space. It consists of a Lie group together with a left-invariant symplectic form $ \omega $. It is known that for a Lie group admitting a left-invariant symplectic form, reductivity implies commutativity, and unimodularity implies solvability. All such groups of dimension $ \leq 4 $ are solvable, but from dimension 6 onwards there are unsolvable symplectic group spaces [3].
References
[1] | A.A. Kirillov, "Elements of the theory of representations" , Springer (1976) (Translated from Russian) |
[2] | V. Guillemin, S. Sternberg, "Geometric asymptotics" , Amer. Math. Soc. (1977) |
[3] | B.-Y. Chu, "Symplectic homogeneous spaces" Trans. Amer. Math. Soc. , 197 (1974) pp. 145–159 |
[4] | Ph.B. Zwart, W.M. Boothby, "On compact, homogeneous symplectic manifolds" Ann. Inst. Fourier , 30 : 1 (1980) pp. 129–157 |
[5] | N.E. Hurt, "Geometric quantization in action" , Reidel (1983) |
[6] | D.V. Alekseevskii, A.M. Vinogradov, V.V. Lychagin, "The principal ideas and methods of differential geometry" , Encycl. Math. Sci. , 28 , Springer (Forthcoming) pp. Chapt. 4, Sect. 5 (Translated from Russian) |
Comments
See Lie differentiation for the definitions of Lie derivative and interior multiplication.
Symplectic homogeneous space. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Symplectic_homogeneous_space&oldid=14939