Seminar talk, 19 October 2016: Difference between revisions

Latest revision as of 15:47, 12 October 2016

Title: Second order partial differential equations with a simple symmetry group

Abstract:
Let $(M=G/H,C)$ be the homogeneous space of a simple Lie group with an invariant contact distribution, which locally defined by a contact form $\theta$ . The non-degenerate 2-form $\omega :=d\theta |_{C}$ is defined up to a conformal multiplier. The manifold $M^{(1)}$ of Lagrangian planes in $C_{p},\,p\in M$ is the total space of the bundle $\pi :M^{(1)}\to M$ . The fiber is the Grassmannian $LGr_{n}$ of the Lagrangian planes of symplectic vector space $\mathbb {R} ^{2n}\simeq C_{p}$ . The group $G$ acts on $M^{(1)}$ as the automorphisms group, and the $G$ -invariant hypersurfaces $E\subset M^{(1)}$ are 2nd order equations with the symmetry group $G$ .

The talk will discuss the description of such hypersurfaces in the case when $M=G/H$ is the adjoint manifold of a simple complex Lie group $G$ , i.e., the orbit $M=\mathrm {Ad} _{G}[E_{\mu }]$ of a highest vector of Lie algebra ${\mathfrak {g}}$ in the projective space $P{\mathfrak {g}}$ .

The talk is based on the joint work with Jan Gutt, Gianni Manno, and Giovanni Moreno.

References:
arXiv:1606.02633

@@ Line 2: / Line 2: @@
 | speaker = Dmitri Alekseevsky
 | title = Second order partial differential equations with a simple symmetry group
-| abstract = Let <math>(M = G/H, C)</math> be homogeneous space of a simple Lie group with an invariant contact distribution, which locally defined by a contact form <math>\theta</math>.  The non-degenerate 2-form <math>\omega := d\theta |_{C}</math> is defined up to a conformal multiplier.  The manifold <math>M^{(1)}</math> of Lagrangian planes in <math>C_p , \, p \in M</math> is the total space of the bundle <math>\pi : M^{(1)} \to M</math>.  The fiber is the Grassmannian <math>LGr_n</math> of the  Lagrangian planes of symplectic vector space <math>\mathbb{R}^{2n} \simeq  C_p</math>.  The group <math>G</math> acts on <math>M^{(1)}</math> as the automorphisms group, and the <math>G</math>-invariant hypersurfaces <math>E \subset M^{(1)}</math> are 2nd order equations with the symmetry group <math>G</math>.
+| abstract = Let <math>(M = G/H, C)</math> be the homogeneous space of a simple Lie group with an invariant contact distribution, which locally defined by a contact form <math>\theta</math>.  The non-degenerate 2-form <math>\omega := d\theta |_{C}</math> is defined up to a conformal multiplier.  The manifold <math>M^{(1)}</math> of Lagrangian planes in <math>C_p , \, p \in M</math> is the total space of the bundle <math>\pi : M^{(1)} \to M</math>.  The fiber is the Grassmannian <math>LGr_n</math> of the  Lagrangian planes of symplectic vector space <math>\mathbb{R}^{2n} \simeq  C_p</math>.  The group <math>G</math> acts on <math>M^{(1)}</math> as the automorphisms group, and the <math>G</math>-invariant hypersurfaces <math>E \subset M^{(1)}</math> are 2nd order equations with the symmetry group <math>G</math>.
-The talk will discuss the description of such hypersurfaces in the case when <math>M=G/H</math> is the adjoint manifold of a simple complex Lie group <math>G</math>, i.e., the orbit <math>M = \mathrm{Ad}_G [E_{\mu}]</math> of a highest weight vector of Lie algebra <math>\mathfrak{g}</math> in the projective space <math>P\mathfrak{g}</math>.
+The talk will discuss the description of such hypersurfaces in the case when <math>M=G/H</math> is the adjoint manifold of a simple complex Lie group <math>G</math>, i.e., the orbit <math>M = \mathrm{Ad}_G [E_{\mu}]</math> of a highest vector of Lie algebra <math>\mathfrak{g}</math> in the projective space <math>P\mathfrak{g}</math>.
 The talk is based on the joint work with  Jan Gutt, Gianni Manno, and Giovanni Moreno.

Seminar talk, 19 October 2016: Difference between revisions

Latest revision as of 15:47, 12 October 2016

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