Earth's atmosphere hosts a rich spectrum of phenomena that involve interactions of a variety of processes across many length and time scales. A systematic approach to analyzing these scale dependent processes is a core task of theoretical meteorology and a prerequisite to constructing reliable computational models for weather forecasting and climate simulation.

Lecture I: The fundamental tools of similarity theory and formal single scale asymptotics will allow us to systematize the large zoo of scale-dependent model equations that one finds in modern textbooks of theoretical meteorology.

Lecture II: The meteorological analogue of the incompressible flow equations are the "anelastic" and "pseudo-incompressible" models. Here we will learn how the presence of internal gravity waves in the atmosphere implies an asymptotic three-scale problem that renders the formal derivation and justification of these models much more intricate than the classical low Mach number derivation of the incompressible flow equations.

Lecture III: The mechanisms by which tropical storms develop into hurricanes and typhoons are still under intense debate despite decades of research. A recent theory for the dynamics of strongly tilted atmospheric vortices will show how asymptotic methods help structuring this scientific debate, and how they offer new angles of scientific attack on the problem.

Lecture IV: This last lecture will summarize some ramifications of the scaling regimes and scaling theories considered in Lectures I-III on the construction of reliable computational methods.

Analysis of large systems of interacting particles is a key for predicting and understanding various phenomena arising in different contexts, from physics (in understanding e.g. boson stars) to social studies (when modeling social networks). Since the number of particles is usually very large one would like to understand qualitative and quantitative properties of such systems of particles through some macroscopic, averaged characte-ristics. In order to identify macroscopic behavior of multi-particle systems, it is helpful to study the asymptotic behavior when the number of particles approaches infinity, with the hope that the limit will approximate properties observed in the systems with a large finite number of particles. An example of an important phenomenon that describes such macroscopic behavior of a large system of particles is the Bose-Einstein condensation. Mathematical models have been developed to understand such phenomena. Those models connect large quantum systems of interacting particles and nonlinear PDE that are d erived from such systems in the limit of the number of particles going to infinity. In this mini-course we will focus on developments that connect a quantum many particle system of bosons and the nonlinear Schrodinger equation, and will apply some of the ideas appearing in this context to a new program of studying well-posedness of Boltzmann equation, which describes the evolution of the probability density of independent identically distributed particles modeling a rarefied gas with predominantly binary elastic interactions.

In this series of lectures, we discuss the construction of weak solutions to the Navier-Stokes equations which have an intermittent singular behaviour. These weak solutions have bounded kinetic energy, possess a limited degree of regularity, and they behave badly on a "thin" set in space-time. In particular, the Lp norms of these solutions vary greatly with p. The construction combines the ideas of convex-integration, as developed in the context of hydrodynamic models by De Lellis and Szekelihidi, with the concept of intermittent Beltrami blocks, introduced in joint works with Buckmaster.

Conserved or dissipated quantities, like energy or entropy, are at the heart of the study of many classes of time-dependent PDEs in connection with fluid mechanics. This is the case, for instance, for the Euler and Navier-Stokes equations, for systems of conservation laws, and for transport equations. In all these cases, a formally conserved quantity may no longer be constant in time for a weak solution at low regularity. The delicate interplay between regularity and conservation of the respective quantity relates to renormalisation in the DiPerna-Lions theory of transport and continuity equations, and to Onsager's Conjecture in the realm of ideal incompressible fluids. We will review the classical commutator methods of DiPerna-Lions and Constantin-E-Titi, and then proceed to more recent results, possibly including an introduction to the technique of convex integration.

Main speakers

1. Rupert Klein
2. Emil Wiedemann
3. Vlad Vicol
4. Natasa Pavlovic

Participating organizers

5. Milan Pokorny
6. Miroslav Bulicek
7. Mirko Rokyta
8. Josef Malek
9. Ondrej Kreml
10. Antonin Novotny
11. Eduard Feireisl

Participants

12. Michele Dolce
13. Marija Galic
14. Pablo Alexei Gazca Orozco
15. Ana Radosevic
16. Gabriel Sattig
17. Simon Schulz
18. Grgur Valentic
19. Amrita Ghosh
20. Sonakshi Sachdev
21. Lars Eric Hientzsch
22. Tomasz Debiec
23. Jakub Kmec
24. Yong Lu
25. Szymon Cygan
26. Erika Maringova
27. Wojciech Szkolka
28. Michal Bathory
29. Nicola Zamponi
30. Jakub Skrzeczkowski
31. Szymon Gorka
32. Lukasz Chomienia
33. Matteo Caggio
34. Elena Salguero
35. Hana Mizerova
36. Petr Kaplicky
37. Mîndrila Claudiu
38. Nilasis Chaudhuri
39. Mark Steinhauer
40. Andreas Schmidt
41. Emil Skrisovsky
42. Martina Hofmanova
43. Danica Basaric
44. Simon Axmann
45. Jiri Malik
46. Simon Markfelder
47. Vaclav Macha
48. Roman Shvydkoy
49. Joseph Miller
50. Mark Dostalik
51. Tomas Los
52. Aneta Wroblewska-Kaminska
53. Sarka Necasova
54. Anna Abbatiello
55. Martin Kalousek
56. Malte Kampschulte
57. Jan Scherz
58. Matthias Sroczinski
59. Tong Tang
60. Sourav Mitra
61. Jack Skipper
62. David Hruska
63. Tabea Tscherpel
64. Dennis Gallenmueller
65. Ibrokhimbek Akramov
66. Hiroshi Wakui
67. Oldrich Ulrych
68. Hana Bilkova