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@ARTICLE{AR-CMGC-20-56, author = {Emery, C.M. and Biancamaria, S. and Boone, A. and Ricci, S. and Rochoux, M. and Pedinotti, V. and David, C.A. }, title = {Assimilation of wide-swath altimetry water elevation anomalies to correct large-scale river routing model parameters}, year = {2020}, volume = {24}, pages = {2207–2233}, doi = {10.5194/hess-24-2207-2020}, journal = {Hydrology and Earth System Sciences}, pdf = {https://cerfacs.fr/wp-content/uploads/2020/05/Globc-Article-Rochoux-hess-24-2207-2020.pdf}}

@ARTICLE{AR-CMGC-20-50, author = {Fisher, R.A. and Koven, C.D. }, title = {Perspectives on the future of land surface models and the challenges of representing complex terrestrial systems}, year = {2020}, number = {4}, volume = {12}, pages = {e2018MS001453}, doi = {10.1029/2018MS001453}, journal = {Journal of Advances in Modeling Earth Systems}, pdf = {https://cerfacs.fr/wp-content/uploads/2020/05/GlobC-Article-fisher-AGUJAMES-2020.pdf}}

@ARTICLE{AR-CMGC-20-44, author = {Bonnet, R. and Boé, J. and Habets, F. }, title = {Influence of multidecadal variability on high and low flows:the case of the Seine basin}, year = {2020}, volume = {24}, pages = {1611–1631}, doi = {10.5194/hess-24-1611-2020}, journal = {Hydrology and Earth System Sciences}, url = {https://www.hydrol-earth-syst-sci.net/24/1611/2020/hess-24-1611-2020.pdf}}

@ARTICLE{AR-CFD-20-45, author = {Wirtz, J. and Cuenot, B. and Riber, E. }, title = {Numerical Study of a Polydisperse Spray Counterflow Diffusion Flame}, year = {2020}, volume = {38}, journal = {Proceedings of the Combustion Institute}, abstract = {A counterflow two-phase diffusion flame with polydisperse spray is numerically studied in a 2D configuration, using a Lagrangian formalism for the liquid phase and accurate combustion chemistry. Results exhibit a very complex double flame structure with diffusion and premixed flames, as well as group and individual droplet burning. Monodisperse two-phase counterflow flames are also computed to help analysing the polydisperse flame, and confirm the strong link between droplet diameter and flame regime. For small droplet diameters, the flame has the same structure than a gaseous flame at a different equivalence ratio, and the flame power increases with the droplet size. For larger droplets, the premixed mode becomes dominant and the flame power exceeds the maximum gaseous diffusion flame power.}, keywords = {ARC, Counter-flow diffusion, Spray, Droplet}}

@ARTICLE{AR-CFD-20-49, author = {Wissocq, G. and Boussuge, J.-F. and Sagaut, P. }, title = {Consistent vortex initialization for the athermal lattice Boltzmann method}, year = {2020}, number = {4}, volume = {101}, pages = {043306 }, doi = {10.1103/PhysRevE.101.043306}, journal = {Physical Review E}, abstract = {A barotropic counterpart of the well-known convected vortex test case is rigorously derived from the Euler equations along with an athermal equation of state. Starting from a given velocity distribution corresponding to an intended flow recirculation, the athermal counterpart of the Euler equations are solved to obtain a consistent density field. The present initialization is assessed on a standard lattice Boltzmann solver based on the D2Q9 lattice. Compared to the usual isentropic initialization, a much lower spurious relaxation toward the targeted solution is observed, which is due to the spatial resolution rather than approximated macroscopic quantities. The amplitude of the spurious waves can be further reduced by including an off-equilibrium part in the initial distribution functions. }, keywords = {lattice Boltzmann method}, url = {https://journals.aps.org/pre/abstract/10.1103/PhysRevE.101.043306}}