Schedule
Monday, 16 March (CM107)
13.15 - 13.30: Registration
13.30 - 14.30: M Shapiro - 1
14.00 - 15.00: Tea/Coffee (CM105)
15.00 - 16.00: M Shapiro - 2
16.15 - 17.15: Exercises - 1
Tuesday, 17 March (CM107)
09.30 - 10.30: M Shapiro - 3
10.30 - 11.00: Tea/Coffee (CM105)
11.00 - 12.00: M Shapiro - 4
12.00 - 13.30: Lunch break
13.30 - 14.30: Exercises - 2
14.30 - 15.00: Tea/Coffee (CM105)
15.00 - 16.00: R Marsh - 1
16.15 - 17.15: R Marsh - 2
Wednesday, 18 March (CM221)
09.30 - 10.30: M Shapiro - 5
10.30 - 11.00: Tea/Coffee (CM219)
11.00 - 12.00: M Shapiro - 6
12.00 - 14.00: Lunch break
14.00 - 15.00: A Veselov - 1
15.00 - 15.30: Tea/Coffee (CM219)
15.30 - 16.30: A Veselov - 2
Thursday, 19 March (CM107)
09.30 - 10.30: M Shapiro - 7
10.30 - 11.00: Tea/Coffee (CM105)
11.00 - 12.00: M Shapiro - 8
12.00 - 14.00: Lunch break
14.00 - 15.00: S Franco
- 1
15.00 - 15.30: Tea/Coffee (CM105)
15.30 - 16.30: S Abenda
Friday, 20 March (CM107)
10.00 - 11.00: M Shapiro - 9
11.00 - 11.30: Tea/Coffee (CM105)
11.30 - 12.30: M Shapiro - 10
12.30 - 14.00: Lunch break
14.00 - 15.00: S Franco - 2
15.00 - 15.30: Tea/Coffee (CM105)
15.30 - 16.30: S Franco - 3
Simonetta Abenda
Totally positive Grassmannians and a class of multisoliton-solution of KP-II: an algebro-geometric approach
The aim of our research is to connect two areas of mathematics: the theory of totally positive Grassmannians and the rational degenerations of m-curves using the theory of the Kadomtsev-Petviashvili 2 equation. The results presented are in collaboration with P.G. Grinevich.
Sebastian Franco
Quantum field theory, cluster algebras and geometric approaches to scattering amplitudes
- Brane tilings (dimer models, quivers and their connection to geometry)
- Dimer models and cluster integrable systems
- On-shell diagrams, the amplituhedron and bipartite field theories
Robert Marsh
- Laurent sequences arising from mutation-periodic quivers.
- The homogeneous coordinate ring of the Grassmannian as a cluster algebra.
Alexander Veselov
Toda lattice and spectral theory of Jacobi matrices.