Millionschikov D.V. Growth of Lie algebras and integrability: Difference between revisions

Latest revision as of 08:40, 4 January 2025

Title: Growth of Lie algebras and integrability

Abstract:
We consider naturally graded Lie algebras ${\mathfrak {g}}=\oplus _{i=1}^{n}{\mathfrak {g}}_{i},\;[{\mathfrak {g}}_{1},{\mathfrak {g}}_{i}]={\mathfrak {g}}_{i+1},\;i\geq 1.$

In the finite-dimensional case they are called Carnot algebras and play an important role in non-holonomic geometry and geometric control theory. A naturally graded Lie algebra ${\mathfrak {g}}$ is generated by ${\mathfrak {g}}_{1}$ and one can define its natural growth function $F_{\mathfrak {g}}^{gr}(n)=\sum _{i=1}^{n}\dim {{\mathfrak {g}}_{i}}$ which is well-defined.

It turned out that the characteristic Lie algebras $\chi$ of some nonlinear hyperbolic partial differential equations are precisely such positively graded Lie algebras. The integability of these equations in the sense of Darboux or higher symmetries leads to the slow growth of $\chi$ .

I will also try to discuss another geometric integrability, the integrability of complex structures on Carnot algebras. It turns out that in this case, on the contrary, Lie algebras must grow sufficiently fast.

Video

Event: One day workshop in honor of Maxim Pavlov's 60th birthday, 14 December 2022, Independent University of Moscow

@@ Line 2: / Line 2: @@
 | speaker = Dmitry Millionschikov
 | title = Growth of Lie algebras and integrability
-| abstract = We consider naturally graded Lie algebras
+| abstract = We consider naturally graded Lie algebras&nbsp;&nbsp;&nbsp;<math>{\mathfrak g} = \oplus_{i = 1}^{n}{\mathfrak g}_i, \; [{\mathfrak g}_1, {\mathfrak g} _i]={\mathfrak g}_{i + 1}, \; i \ge 1.</math>
-<math>
-{\mathfrak g} = \oplus_{i = 1}^{n}{\mathfrak g}_i, \; [{\mathfrak g}_1, {\mathfrak g} _i]={\mathfrak g}_{i + 1}, \; i \ge 1.
-</math>
 In the finite-dimensional case they are called Carnot algebras and play an important role in non-holonomic geometry and geometric control theory. A naturally graded Lie algebra <math>{\mathfrak g}</math> is generated by <math>{\mathfrak g}_1</math> and one can define its natural growth function <math> F_{\mathfrak g}^{gr}(n)=\sum_{i=1}^n\dim{{\mathfrak g}_i} </math> which is well-defined.
@@ Line 12: / Line 8: @@
 It turned out that the characteristic Lie algebras <math>\chi</math> of some nonlinear hyperbolic partial differential equations are precisely such positively graded Lie algebras. The integability of these equations in the sense of Darboux  or higher symmetries leads to the slow growth of <math>\chi</math>.
-I will also try to discuss another geometric integrability, the integrability of complex structures on Carnot algebras. It turns out that in this case, o
+I will also try to discuss another geometric integrability, the integrability of complex structures on Carnot algebras. It turns out that in this case, on the contrary, Lie algebras must grow sufficiently fast.
-n the contrary, Lie algebras must grow sufficiently fast.
+| video = https://video.gdeq.org/GDEq-zoom-seminar-Pavlov60-conf-20221214-3-Dmitry_Millionschikov.mp4
-| video =
 | slides =
 | references =

Millionschikov D.V. Growth of Lie algebras and integrability: Difference between revisions

Latest revision as of 08:40, 4 January 2025

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