200 Years of Navier-Stokes and Turbulences

July 31st - August 25th
Les Houches, France
The program and abstracts are available [here].
Live stream is available [here].
Videos of lectures are available [here (remote server) and here (local server)]. 
Slides of lectures are available [here].
Going to Mer de Glace [here].
Link for feedback form [here].

 Week 1
 Week 2


Mickaël Bourgoin – C.N.R.S. / ENS de Lyon / Phys. Lab., France
Nicolas Mordant – Univ. Grenoble Alpes / L.E.G.I., France
Aurore Naso – C.N.R.S. / L.M.F.A., France
John Christos Vassilicos – C.N.R.S. / L.M.F.L., France


2023 will be the bicentenary of Navier’s work that led to the establishment of the master equations of fluid mechanics, known as the Navier-Stokes equations, which are intrinsically linked to Turbulence, certainly one of the most common phenomena around us but also one of the most complex fields in physics. Far from being purely symbolic, this anniversary is an important event and the opportunity to take stock of the evolution of Navier-Stokes Turbulence research over 200 years and of its future prospects.

Because of their age, the Navier-Stokes equations are often ambiguously qualified as "classic", thus risking the suggestion that nothing important remains to be discovered in fluid mechanics, whereas paradoxically, despite 200 years of active research, the discipline retains an unwavering youth. On the one hand, because the complexity of the Navier-Stokes equations means that study remains of central and broad relevance, their mathematical properties and physical implications remaining far from having been fully disclosed, in particular when it comes to the understanding of turbulent flows. On the other hand, because the major contemporary challenges that humankind must urgently face, such as climate, the environment, ecological transition and public health are inseparable from the need for major scientific advances in the understanding and modelling of Navier-Stokes Turbulence. Indeed, the bicentenary of the Navier-Stokes equations reminds us that their very birth carries the trace of an intrinsic interconnectedness as Navier was both a mathematician and a bridge engineer, anticipating a long inter-and-multi-disciplinary tradition. Ranked among the 7 mathematical problems of the millennium by the Clay society, the Navier-Stokes equations is also often cited as one of the most important equations in physics and remains at the heart of many natural sciences and industrial applications.

The bicentennial of the Navier-Stokes equations also comes at a time when Turbulence research appears to have reached a certain degree of maturity, manifested in particular by the increasing number if bridges the discipline has built with other fields of science. Concepts intimately associated to the physics of Navier-Stokes Turbulence are now commonly linked to other disciplines as varied as quantum mechanics, wave physics, optics, active matter, granular media, etc. well beyond the physics of flows. It is to be hoped that these transdisciplinary bridges will also, in turn, contribute to fostering fundamental advances in unravelling the mysteries of  the Navier-Stokes equations.

The aim of this school is to provide to Phd students, post-docs and young scientists lectures given by world experts on fundamentals aspects Navier-Stokes turbulence, reviewing both the accumulated knowledge over the past 200 years and the remaining challenges, open questions and new fields to be explored by next generations of scientists.

Confirmed Lecturers

Edriss Titi - Cambridge Univ.
Vlad Vicol - NYU
Bérengère Dubrulle - CNRS / CEA Saclay
Carlo Cossu - CNRS / LHEEA
Bérengère Poidvin - CNRS / EM2C
Joachim Peinke - Univ. Oldenburg
Gregory Falkovich - Weizman Institute
Eric Lamballais - CNRS / Institut P'
Bjorn Hof - Institute of Science and Technology Austria
Ilya Karlin - ETH Zurich
Alexander Smits - Princeton
Juan Pedro Mellado - University of Hamburg
Alain Pumir - CNRS / Lab. Physique ENS de Lyon
Sebastien Galtier - Univ. Paris Saclay / LPP
Herman Clercx - Eindhoven University of Technology
Mathieu Gibert - CNRS / Institut Néel


Navier-Stokes: from the maths to the actual fluid

- Mathematical aspects 

- Dissipation and singularities

- Reduction of NS: LES, POD and other reduced models 

- Learning approaches

Navier-Stokes and Statistical Physics

- Entropy, cascade and Large scales

- Lagrangian Dynamics and Irreversibility

- Transition to turbulence as a percolation phase transition

- Simulations Lattice Boltzmann


Beyond stationary homogeneous turbulence and toward classes of universal principles for a wide range of turbulent flows

- New phenomenology of non-stationary turbulence 

- Wall turbulence 

- Entrainment and Interfaces

- Turbulence with waves, wave turbulence: Stratified and or rotating turbulence

- Turbulent Rayleigh-Bénard and Taylor Couette

- Cryogenic turbulence: turbulence without viscosity 




The program and abstracts are available [here, download full program].