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Room P3.10, Mathematics Building
Integrability, Geometry, Asymptotics
Justin Forlano, Monash University.
The intermediate nonlinear Schrödinger equation.
Seminars, for informal dissemination of research results, exploratory work by research teams, outreach activities, etc., constitute the simplest form of meetings at a Mathematics research centre.
CAMGSD has recorded the calendar of its seminars for a long time, this page serving both as a means of public announcement of forthcoming activities but also as a historic record.
For a full search interface see the Mathematics Department seminar page.
Room P3.10, Mathematics Building
Integrability, Geometry, Asymptotics
Justin Forlano, Monash University.
The intermediate nonlinear Schrödinger equation.
Room P3.10, Mathematics Building
Lisbon WADE — Webinar in Analysis and Differential Equations
Justin Forlano, Monash University.
The intermediate nonlinear Schrödinger equation.
In this talk, I will discuss recent results regarding the intermediate nonlinear Schrödinger equation (INLS). Analytically, INLS is a one-dimensional completely integrable nonlinear Schrödinger equation with a cubic derivative nonlinearity and is $L^2$-critical. A limiting form of INLS is the continuum Calogero-Moser equation (CCM), which is also completely integrable. Interestingly, CCM keeps the Hardy space $L^2_+$ invariant, and, under this assumption, tools from complete integrability have recently resolved the well-posedness problem for CCM in $L^2_+$. I will discuss progress on the well-posedness for INLS and CCM (not relying on complete integrability), outside of the Hardy space and in low-regularity. Our approach combines a gauge transformation, bilinear Strichartz estimates and a refined decomposition for smooth solutions. This is based on joint work with A. Chapouto (CNRS, Monash) and T. Laurens (UW-Madison).
Room P3.10, Mathematics Building
Integrability, Geometry, Asymptotics
Andreia Chapouto, Monash University.
Gauge transform for the Korteweg-de Vries equation and well-posedness below the $H^{-1}$-scale.
In this talk, we consider the low regularity well-posedness problem for the Korteweg-de Vries equation (KdV) on the real line. Aiming to bridge the regularity gap between the scaling critical space and the known optimal well-posedness in $L^2$-based Sobolev spaces, we consider rough data in Fourier-Lebesgue spaces. Via infinite normal form reductions and exploiting algebraic cancellations, we introduce a new gauged KdV equation, equivalent to the original one at high regularity, but better behaved for rough solutions below the $H^{-1}$-scale. Surprisingly, our method does not rely on the completely integrable structure of KdV and is easily adapted to other equations with quadratic derivative nonlinearities, such as the dispersion-generalized Benjamin-Ono equations.
This talk is based on joint work with Simão Correia (IST, U. Lisboa) and João Pedro Ramos (IMPA).
Room P3.10, Mathematics Building
Lisbon WADE — Webinar in Analysis and Differential Equations
Andreia Chapouto, Monash University.
Gauge transform for the Korteweg-de Vries equation and well-posedness below the $H^{-1}$-scale.
Room P4.35, Mathematics Building
Max Reinhold Jahnke, Universität zu Köln.
Cohomology of CR structures on compact Lie groups.
We show that, under a division condition, the tangential Cauchy-Riemann cohomology of a compact Lie group with a left-invariant CR structure can be computed on a suitable maximal torus. As a consequence, we conclude that the tangential Cauchy-Riemann cohomology is finite-dimensional. We also show that, for a class of CR structures, this division condition is necessary for the total cohomology to be finite-dimensional. The proof combines Fourier analysis on compact Lie groups, highest-weight representations and Lie algebra cohomology. This not only generalizes but provides completely new proofs for the analogous result due to Pittie and for its extensions to Levi-flat CR structures, obtained by Jacobowitz and Jahnke.
Room P3.10, Mathematics Building
Integrability, Geometry, Asymptotics
Qiao Huang, Southeast University.
Cartan--Schouten Connections: Geometric Reduction and a Connection-Dependent Variational Principle.
We study the family of Cartan--Schouten connections on Lie groups, parameterized by $\lambda\in[0,1]$, whose geodesics through the identity are one-parameter subgroups. We compute their curvature, torsion, parallel transport, and geodesics, and develop Euler--Poincar\'e and Lie--Poisson reduction for mechanical systems via these connections, unifying the "minus'" and `"plus" cases. These inspire us to introduce a connection-dependent variational principle where the Lagrangian is expressed in terms of the parallel-transported velocity, leading to an integro-differential Euler--Lagrange equation that explicitly involves torsion and curvature memory terms. The general framework is illustrated on two concrete examples: the Heisenberg group, where the equations simplify to an ODE system, and the rotation group SO(3), where the integro-differential system is solved numerically via a Magnus expansion.