BEGIN:VCALENDAR VERSION:2.0 PRODID:-//132.216.98.100//NONSGML kigkonsult.se iCalcreator 2.20.4// BEGIN:VEVENT UID:20250709T194727EDT-4208BujtHK@132.216.98.100 DTSTAMP:20250709T234727Z DESCRIPTION:Title:  A Liouville type theorem in sub-Riemannian geometry\, a nd applications to several complex variables\n Abstract:  The Riemann mappi ng theorem tells us that any simply connected planar domain is conformally equivalent to the disk. This provides a classification of simply connecte d domains via conformal maps. This classification fails in higher dimensio nal complex spaces\, as already Poincare' had proved that bi-discs are not bi-holomorphic to the ball. Since then\, mathematicians have been looking for criteria that would allow to tell whether two domains are bi-holomorp hic equivalent. In the early 70's\, after a celebrated result by Moser and Chern\, the question was reduced to showing that any bi-holomorphism betw een smooth\, strictly pseudo-convex domains extends smoothly to the bounda ry. This was established by Fefferman\, in a 1974 landmark paper. Since th en\, Fefferman's result has been extended and simplified in a number of wa ys. About 10 years\, ago Michael Cowling conjectured that one could prove the smoothness of the extension by using minimal regularity hypothesis\, t hrough an argument resting on ideas from the study of quasiconformal maps. In its simplest form\, the proposed proof is articulated in two steps: (1 ) prove that any bi-holomorphism between smooth\, strictly pseudoconvex do mains extends to a homeomorphisms between the boundaries that is 1-quasico nformal with respect to the sub-Riemannian metric associated to the Levi f orm\; (2) prove a Liouville type theorem\, i.e. any $1-$quasiconformal hom eomorphism between such boundaries is a smooth diffeomorphism. In this tal k I will discuss recent work with Le Donne\, where we prove the first step of this program\, as well as joint work with Citti\, Le Donne and Ottazzi \, where we settle the second step\, thus concluding the proof of Cowling' s conjecture. The proofs draw from several fields of mathematics\, includi ng nonlinear partial differential equations\, and analysis in metric space s. \n DTSTART:20180214T183000Z DTEND:20180214T193000Z LOCATION:Room 920\, Burnside Hall\, CA\, QC\, Montreal\, H3A 0B9\, 805 rue Sherbrooke Ouest SUMMARY:Luca Capogna (Worcester Polytechnic Institute) URL:/mathstat/channels/event/luca-capogna-worcester-po lytechnic-institute-285080 END:VEVENT END:VCALENDAR