Chercheur senior

Mécanique des fluides numérique

+33(0)5 61 19 31 15

Eleonore.Riber@cerfacs.fr

Chercheur senior

Mécanique des fluides numérique

+33(0)5 61 19 31 15

Eleonore.Riber@cerfacs.fr

Jaravel, T., Riber, E., Cuenot, B. and Bulat, G. (2016) Large Eddy Simulation of a model gas turbine burner using reduced chemistry with accurate pollutant prediction, Proceedings of the Combustion Institute, 36 (3), pp. 3817–3825, doi:10.1016/j.proci.2016.07.027 Shum Kivan, F., Marrero-Santiago, J., Verdier, A., Riber, E., Renou, B., Cabot, G. and Cuenot, B. (2016) Experimental and numerical analysis of a turbulent spray flame structure, Proceedings of the Combustion Institute, 36, doi:10.1016/j.proci.2016.06.039 Cuenot, B., Vicquelin, R., Riber, E., Moureau, V., Lartigue, G., Figuer, A., Mery, Y., Lamouroux, J., Richard, S., Gicquel, L. Y. M., Schmitt, T. and Candel, S. (2016) Advanced Simulation of Aeronautical Combustors, Aerospace Lab, 11 (June), pp. AL11-06 Fiorina, B., Vié, A., Franzelli, B., Darabiha, N., Massot, M., Dayma, G., Dagaut, P., Moureau, V., Vervisch, L., Berlemont, A., Sabelnikov, V., Riber, E. and Cuenot, B. (2016) Modeling Challenges in Computing Aeronautical Combustion Chambers, Aerospace Lab, 11, pp. AL11-05, doi:10.12762/2016.AL11-05 Chaussonnet, G., Vermorel, O., Riber, E. and Cuenot, B. (2016) A new phenomenological model to predict drop size distribution in Large-Eddy Simulations of airblast atomizers, International Journal of Multiphase Flow, 80 (april 2016), pp. 29-42, doi:10.1016/j.ijmultiphaseflow.2015.10.014 Pedot, T., Cuenot, B., Riber, E. and Poinsot, T. (2016) Coupled heat transfers in a refinery furnace in view of fouling prediction, Journal of Heat Transfer, pp. 072101-072101-10, doi:10.1115/1.4033096 Philipp, M., Boileau, M., Vicquelin, R., Riber, E., Schmitt, T., Cuenot, B., Durox, D. and Candel, S. (2015) Large Eddy Simulations of the ignition sequence of an annular multiple-injector combustor, Proceedings of the Combustion Institute, 35 (3), pp. 3159–3166, doi:3159–3166 Esclapez, L., Riber, E. and Cuenot, B. (2015) Ignition probability of a partially premixed burner using LES, Proceedings of the Combustion Institute, 35 (3), pp. 3133–3141, doi:10.1016/j.proci.2014.07.040 Barré, D., Esclapez, L., Cordier, L., Riber, E., Cuenot, B., Staffelbach, G., Renou, B., Vandel, A., Gicquel, L. Y. M. and Cabot, G. (2014) Flame propagation in aeronautical swirled multi-burners: experimental and numerical investigation., Combustion and Flame, 161 (9), pp. 2387-2405, doi:10.1016/j.combustflame.2014.02.006 Masi, E., Simonin, O., Riber, E., Sierra, P. and Gicquel, L. Y. M. (2014) Development of an algebraic-closure-based moment method for unsteady eulerian simulations of particle-laden turbulent flows in very dilute regime, International Journal of Multiphase Flow, 58 (January) Lecocq, G., Poitou, D., Hernandez-Vera, I., Duchaine, F., Riber, E. and Cuenot, B. (2014) A methodology for soot prediction including thermal radiation in complex industrial burners, Flow Turbulence and Combustion, 92 (4), pp. 947-970 Lecocq, G., Hernandez-Vera, I., Poitou, D., Riber, E. and Cuenot, B. (2013) Soot prediction by Large-Eddy Simulation of complex geometry combustion chambers, Comptes Rendus de l’Académie des Sciences – Mécanique, 341 (1-2), pp. 230-237 Auzillon, P., Riber, E., Gicquel, L. Y. M., Gicquel, O., Darabiha, N., Veynante, D. and Fiorina, B. (2013) Numerical investigation of a helicopter combustion chamber using LES and tabulated chemistry, Comptes Rendus Mécanique, 341 (1-2), pp. 257-265 Franzelli, B., Riber, E. and Cuenot, B. (2013) Impact of the chemical description on a Large Eddy Simulation of a lean partially premixed swirled flame, Comptes Rendus Mécanique, 341 (1-2), pp. 247-256 Hannebique, G., Sierra, P., Riber, E. and Cuenot, B. (2013) Large eddy simulation of reactive two-phase flow in an aeronautical multipoint burner, Flow Turbulence and Combustion, 90 (2), pp. 449-469 Hernandez-Vera, I., Lecocq, G., Poitou, D., Riber, E. and Cuenot, B. (2013) Computations of soot formation in ethylene/air counterflow diffusion flames and its interaction with radiation, Comptes Rendus Mécanique, 341 (1-2), pp. 238-246 Hernandez-Vera, I., Lecocq, G., Poitou, D., Riber, E. and Cuenot, B. (2013) Computations of soot formation in ethylene/air counterflow diffusion flames and its interaction with radiation, Comptes Rendus Mécanique, 341 (1-2), pp. 238-246 Franzelli, B., Riber, E., Gicquel, L. Y. M. and Poinsot, T. (2012) Large Eddy Simulation of combustion instabilities in a lean partially premixed swirled flame, cf, 159 (2), pp. 621-637 Franzelli, B., Riber, E., Sanjosé, M. and Poinsot, T. (2010) A two-step chemical scheme for Large Eddy Simulation of kerosene-air flames, Combustion and Flame, 157 (7), pp. 1364-1373 Senoner, J. -M., Sanjosé, M., Lederlin, T., Jaegle, F., Garcia, M., Riber, E., Cuenot, B., Gicquel, L. Y. M., Pitsch, H. and Poinsot, T. (2009) Eulerian and lagrangian large-eddy simulations of an evaporating two-phase flow, Comptes Rendus de l’Académie des Sciences – Mécanique, 337 (6-7), pp. 458-468 Riber, E., Moureau, V., Garcia, M., Poinsot, T. and Simonin, O. (2009) Evaluation of numerical strategies for Large Eddy Simulation of particulate two-phase recirculating flows, Journal of Computational Physics, 228 (2), pp. 539-564 Boileau, M., Pascaud, S., Riber, E., Cuenot, B., Gicquel, L. Y. M., Poinsot, T. and Cazalens, M. (2008) Investigation of two-fluid methods for Large Eddy Simulation of spray combustion in Gas Turbines, Flow Turbulence and Combustion, 80 (3), pp. 291-321

@ARTICLE{AR-CFD-16-171,
author = {Jaravel, T. and Riber, E. and Cuenot, B. and Bulat, G. },
title = {Large Eddy Simulation of a model gas turbine burner using reduced chemistry with accurate pollutant prediction},
year = {2016},
number = {3},
volume = {36},
pages = { 3817–3825},
doi = {10.1016/j.proci.2016.07.027},
journal = {Proceedings of the Combustion Institute},
abstract = {Complying with stringent pollutant emission regulations requires a strong optimization process, for which
Large Eddy Simulation (LES) is a promising tool at the design stage of modern gas turbine combustors. Yet
the accurate prediction of pollutant formation remains a challenge because of the complex flame structure in
this type of configuration. The strategy retained for the present LES study is to employ analytically reduced
mechanism (ARC) with accurate pollutant chemistry in combination with the Dynamic Thickened Flame
model (DTF) in the SGT-100 burner. The reduction of the mechanism is first presented and validated in
the burner operating conditions on canonical cases. Then, comparisons of LES results with the experimental
data show the excellent agreement of velocity statistics and a good agreement in terms of flame shape and
exhaust pollutant prediction. The turbulent flame structure is further analyzed and compared with laminar
unstrained and strained flames. Unmixedness and strain are found to significantly impact pollutant formation
and flame stabilization. The ARC/DTF strategy accounts for these effects with a very good compromise
between cost and accuracy.},
url = {http://www.sciencedirect.com/science/article/pii/S1540748916302838}}

@ARTICLE{AR-CFD-16-174,
author = {Shum Kivan, F. and Marrero-Santiago, J. and Verdier, A. and Riber, E. and Renou, B. and Cabot, G. and Cuenot, B. },
title = {Experimental and numerical analysis of a turbulent spray flame structure},
year = {2016},
volume = {36},
doi = {10.1016/j.proci.2016.06.039},
journal = {Proceedings of the Combustion Institute},
abstract = {An experimental and numerical study of an academic n-heptane/air lab-scale jet spray burner is presented. The objective is to provide new insight on turbulent spray flame complex structures similar to those encountered in industrial combustors by joint experimental and numerical diagnostics. Experimental measurements include PDA for air velocity and droplet size as well as velocity and OH-PLIF images for the flame analysis. Numerical simulations consist in Large Eddy Simulation (LES) coupled to Discrete Particle Simulation for the dispersed phase. The comparison between experiment and simulation confirms the capability of LES to reproduce the gaseous and liquid flow structure in both non-reacting and reacting cases with good accuracy. The lifted stabilized spray flame exhibits a complex shape due to interactions between turbulence, chemistry and evaporation. A detailed analysis shows that both partially-premixed and diffusion flames are present, depending on the capacity of droplets to evaporate. Furthermore, an attempt is made to identify the processes leading to two-phase flame stabilization.}}

@ARTICLE{AR-CFD-16-169,
author = {Cuenot, B. and Vicquelin, R. and Riber, E. and Moureau, V. and Lartigue, G. and Figuer, A. and Mery, Y. and Lamouroux, J. and Richard, S. and Gicquel, L.Y.M. and Schmitt, T. and Candel, S. },
title = {Advanced Simulation of Aeronautical Combustors},
year = {2016},
number = {June},
volume = {11},
pages = {AL11-06},
journal = {Aerospace Lab},
abstract = {Le développement de nouveaux concepts de foyers aéronautiques s’appuie sur la meilleure connaissance possible des phénomènes de combustion comme l’allumage et l’extinction, la structure des flammes, les instabilités de combustion ou les émissions polluantes. La simulation numérique, et en particulier l’approche Simulation aux Grandes Échelles, est un outil puissant pour comprendre, prévoir et contrôler les phénomènes physiques couplés présents en combustion turbulente à la fois dans les configurations académiques et appliquées. Grâce à des modèles physiques fiables, des méthodes numériques précises et la grande efficacité des calculateurs massivement parallèles, la simulation numérique est maintenant capable de fournir des résultats robustes et sûrs dans des géométries complexes en prenant en compte tous les effets physiques et technologiques. Aujourd’hui, c’est un outil de recherche qui contribue à améliorer notre connaissance des écoulements turbulents réactifs et en particulier de l’interaction entre la turbulence et la chimie de la combustion. C’est aussi un outil efficace pour la conception de foyers aéronautiques, permettant de guider les tests sur banc d’essai et, dans certains cas, de réduire leur nombre.},
pdf = {http://cerfacs.fr/wp-content/uploads/2016/09/CFD_CUENOT_AL11-06.pdf}}

@ARTICLE{AR-CFD-16-215,
author = {Fiorina, B. and Vié, A. and Franzelli, B. and Darabiha, N. and Massot, M. and Dayma, G. and Dagaut, P. and Moureau, V. and Vervisch, L. and Berlemont, A. and Sabelnikov, V. and Riber, E. and Cuenot, B. },
title = {Modeling Challenges in Computing Aeronautical Combustion Chambers},
year = {2016},
volume = {11},
pages = {AL11-05},
doi = {10.12762/2016.AL11-05},
journal = {Aerospace Lab},
abstract = {This article reviews the modeling challenges for performing Large Eddy Simulations
of aero-nautical combustion chambers. Since the kerosene is injected in a liquid
phase into the combustion chamber, the description of the atomization is of primary
importance. The article first discusses the numerous numerical challenges encountered
during this process, which leads to the formation of small droplets that constitute
a spray. The existing numerical and modeling methods to describe a spray of kerosene
droplets are then presented. The article then focuses on the description of the complex
combustion kinetics. Hundreds of species and thousands of reactions have to be
considered to predict ignition, flame stabilization and pollutant emissions. Due to lengthy
computational times, detailed chemical schemes are too large to be directly used
in CFD. This article then presents the major existing chemical reduction strategies.
Significant interactions of the reactions layers with the flow vortices occur at the subgrid
scale. The question of turbulent combustion modeling is therefore discussed in an
LES context. Finally, the prediction of soot and NOx formation is presented. The review
is illustrated by several examples representative of practical situations encountered in
aeronautical combustors.},
pdf = {http://cerfacs.fr/wp-content/uploads/2016/09/CFD_RIBER_AL11-05_0.pdf}}

@ARTICLE{AR-CFD-16-26892,
author = {Chaussonnet, G. and Vermorel, O. and Riber, E. and Cuenot, B. },
title = {A new phenomenological model to predict drop size distribution in Large-Eddy Simulations of airblast atomizers},
year = {2016},
number = {april 2016},
volume = {80},
pages = {29-42},
doi = {10.1016/j.ijmultiphaseflow.2015.10.014},
journal = {International Journal of Multiphase Flow},
abstract = {A new atomization model for prefilming airblast atomizers is presented and applied in the Large-Eddy Simulation of an academic experiment. The model, named PAMELA, expresses the drop size Probability Density Function of the spray in the form of a Rosin–Rammler distribution whose parameters depend on flow conditions. A mechanism of liquid fragmentation is proposed where a Rayleigh–Taylor instability develops in the transverse direction. The wavelength of this instability (i) is assumed to be proportional to the Sauter Mean Diameter of the spray, and (ii) scales with a Weber number based on the atomizing edge thickness, providing a first link between flow conditions and the Rosin–Rammler parameters. The second link is found by introducing a second Weber number based on the thickness of the boundary layer developing on the prefilmer. A first comparison with academic experiments shows that the model assumptions are valid and allows to calibrate the model constants. PAMELA is then implemented in a LES solver to perform the numerical simulation of an academic airblast atomizer. The obtained drop size distribution and spatial structure of the spray are in good agreement with measurements, demonstrating the validity of the proposed approach in the context of LES, and that the proposed PAMELA model may now be used to describe the liquid spray in LES of industrial nozzles.}}

@ARTICLE{AR-CFD-16-26895,
author = {Pedot, T. and Cuenot, B. and Riber, E. and Poinsot, T. },
title = {Coupled heat transfers in a refinery furnace in view of fouling prediction},
year = {2016},
pages = {072101-072101-10},
doi = { 10.1115/1.4033096},
journal = {Journal of Heat Transfer},
abstract = {In industrial refinery furnaces, the efficiency of thermal transfer to heat crude oil before distillation is often altered by coke deposition inside the fuel pipes. This leads to increased production and maintenance costs, and requires better understanding and control. Crude oil fouling is a chemical reaction that is, at first order, thermally controlled. In such large furnaces, the predominant heat transfer process is thermal radiation by the hot combustion products, which directly heats the pipes. As radiation fluxes depend on temperature differences, the pipe surface temperature also plays an important role and needs to be predicted with sufficient accuracy. This pipe surface temperature results from the energy balance between thermal radiation, convective heat transfer, and conduction in the solid material of the pipe, meaning that the thermal behavior of the whole system is a coupled radiation–convection–conduction problem. In this work, this coupled problem is solved in a cylindrical furnace, in which the crude oil flowing in vertical pipes is heated. The thermal radiation of combustion gases is modeled using the discrete ordinate method (DOM) with accurate spectral models and is coupled to heat conduction in the pipe to predict its wall temperature. The flame is described with a complex chemistry combustion model. An energy balance confirms that heat transfers are effectively dominated by thermal radiation. Good agreement with available measurements of the radiative heat flux on a real furnace shows that the proposed approach predicts the correct heat transfers to the pipe. This allows an accurate prediction of the temperature field on the pipe surface, which is a key parameter for liquid fouling inside the pipe. This shows that the thermal problem in furnaces can be handled with relatively simple models with good accuracy},
url = {http://heattransfer.asmedigitalcollection.asme.org/article.aspx?articleid=2506748}}

@ARTICLE{AR-CFD-15-27691,
author = {Philipp, M. and Boileau, M. and Vicquelin, R. and Riber, E. and Schmitt, T. and Cuenot, B. and Durox, D. and Candel, S. },
title = {Large Eddy Simulations of the ignition sequence of an annular multiple-injector combustor},
year = {2015},
number = {3},
volume = {35},
pages = {3159–3166},
doi = {3159–3166},
journal = {Proceedings of the Combustion Institute},
abstract = {The ignition transient is a critical fundamental phase in combustion systems that has strong practical implications. While this phenomenon has been extensively studied on single injector configurations, the burner-to-burner propagation of a full annular combustor is rarely investigated, due to the size and complexity of the geometry involved. To this purpose, an annular experimental setup has been developed at EM2C, featuring sixteen swirl injectors and quartz tubes providing a direct optical access to the flame. Ignition has been investigated systematically on this device, thus providing a large experimental database. In this work, this experiment is computed in the Large Eddy Simulation (LES) framework by carrying out massively parallel computations. This constitutes a unique comparison between experiments and calculations of a critical process for gas turbines. The ability of turbulent combustion models to properly retrieve the flame structure and propagation at the largest scales is not yet fully assessed and is investigated in this paper by comparing two conceptually different combustion modeling approaches, namely the filtered tabulated chemistry (F-TACLES) and the flame thickening with reduced chemistry (TFLES). Qualitative and quantitative comparisons between both simulations and experiment show an overall excellent agreement.},
url = {http://dx.doi.org/10.1016/j.proci.2014.07.008}}

@ARTICLE{AR-CFD-15-27693,
author = {Esclapez, L. and Riber, E. and Cuenot, B. },
title = {Ignition probability of a partially premixed burner using LES},
year = {2015},
number = {3},
volume = {35},
pages = {3133–3141},
doi = {10.1016/j.proci.2014.07.040},
journal = {Proceedings of the Combustion Institute},
abstract = {To comply with stringent pollutant emission regulation, low-emission aeronautical gas turbines rely on lean premixed combustion. Such technology raises the issue of ensuring a reliable ignition since the combustor operates closer to blow-off. Ignition is however known as a stochastic phenomenon, associated to various sources of system variability. These variabilities and their impact on the success or failure of ignition are still not fully understood. In this paper, Large Eddy Simulation (LES) of laser ignition sequences in an academic swirled turbulent partially premixed burner are performed to obtain statistical information at three selected ignition locations representative of the various ignition scenarios observed. The velocity and mixing fields are first validated against measurements to eliminate uncertainty associated with the non-reacting flow. LES is then shown to recover the ignition statistical behavior and probability for the selected ignition locations. Moreover, LES analysis allows to identify the various mechanisms that drive ignition failure or success. Statistics of flame displacement speed are used to demonstrate the effect of curvature and stretch in regions of intense turbulence and the impact of partial premixing on the ignition process.},
url = {http://dx.doi.org/10.1016/j.proci.2014.07.040}}

@ARTICLE{AR-CFD-14-20536,
author = {Barré, D. and Esclapez, L. and Cordier, L. and Riber, E. and Cuenot, B. and Staffelbach, G. and Renou, B. and Vandel, A. and Gicquel, L.Y.M. and Cabot, G. },
title = {Flame propagation in aeronautical swirled multi-burners: experimental and numerical investigation.},
year = {2014},
number = {9},
volume = {161},
pages = {2387-2405},
doi = {10.1016/j.combustflame.2014.02.006},
journal = {Combustion and Flame},
url = {http://www.sciencedirect.com/science/journal/00102180/161/9}}

@article{AR-CFD-14-21240,
author = {Masi, E. and Simonin, O. and Riber, E. and Sierra, P. and Gicquel, L.Y.M. },
title = {Development of an algebraic-closure-based moment method for unsteady eulerian simulations of particle-laden turbulent flows in very dilute regime},
year = {2014},
number = {January},
volume = {58},
pages = {},
journal = {International Journal of Multiphase Flow}}

@ARTICLE{AR-CFD-14-21201,
author = {Lecocq, G. and Poitou, D. and Hernandez-Vera, I. and Duchaine, F. and Riber, E. and Cuenot, B. },
title = {A methodology for soot prediction including thermal radiation in complex industrial burners},
year = {2014},
number = {4},
volume = {92},
pages = {947 - 970},
journal = {Flow Turbulence and Combustion}}

@article{AR-CFD-13-21200,
author = {Lecocq, G. and Hernandez-Vera, I. and Poitou, D. and Riber, E. and Cuenot, B. },
title = {Soot prediction by Large-Eddy Simulation of complex geometry combustion chambers},
year = {2013},
number = {1-2},
volume = {341},
pages = {230 - 237},
journal = {Comptes Rendus de l’Académie des Sciences – Mécanique}}

@ARTICLE{AR-CFD-13-20526,
author = {Auzillon, P. and Riber, E. and Gicquel, L.Y.M. and Gicquel, O. and Darabiha, N. and Veynante, D. and Fiorina, B. },
title = {Numerical investigation of a helicopter combustion chamber using LES and tabulated chemistry},
year = {2013},
number = {1-2},
volume = {341},
pages = {257 - 265},
journal = {Comptes Rendus Mécanique}}

@ARTICLE{AR-CFD-13-20910,
author = {Franzelli, B. and Riber, E. and Cuenot, B. },
title = {Impact of the chemical description on a Large Eddy Simulation of a lean partially premixed swirled flame},
year = {2013},
number = {1-2},
volume = {341},
pages = {247 - 256},
journal = {Comptes Rendus Mécanique}}

@ARTICLE{AR-CFD-13-21034,
author = {Hannebique, G. and Sierra, P. and Riber, E. and Cuenot, B. },
title = {Large eddy simulation of reactive two-phase flow in an aeronautical multipoint burner},
year = {2013},
number = {2},
volume = {90},
pages = {449 - 469},
journal = {Flow Turbulence and Combustion},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_12_65.pdf}}

@ARTICLE{AR-CFD-13-21047,
author = {Hernandez-Vera, I. and Lecocq, G. and Poitou, D. and Riber, E. and Cuenot, B. },
title = {Computations of soot formation in ethylene/air counterflow diffusion flames and its interaction with radiation},
year = {2013},
number = {1-2},
volume = {341},
pages = {238 - 246},
journal = {Comptes Rendus Mécanique},
abstract = {A methodology is presented which allows to predict soot levels produced in simple, one-dimensional laminar flames. The method is applied to the calculation of a set of well documented ethylene/air counterflow diffusion flames, using a detailed chemical mechanism (Davis et al., 1999 [1]) and a semi-empirical, two-equation soot model from Leung and Lindstedt (1991) [2]. Modifications of the original soot model are made in order to retrieve the experimental measurements of Hwang and Chung (2001) [3]. To account for radiative heat losses, a second series of fully coupled gas/soot/radiation simulations of the counterflow flames is performed. This allows to assess the effect of soot and gas radiation on soot formation and on the flame structure.},
url = {http://www.sciencedirect.com/science/article/pii/S1631072112002136}}

@ARTICLE{AR-CFD-13-26420,
author = {Hernandez-Vera, I. and Lecocq, G. and Poitou, D. and Riber, E. and Cuenot, B. },
title = {Computations of soot formation in ethylene/air counterflow diffusion flames and its interaction with radiation},
year = {2013},
number = {1-2},
volume = {341},
pages = {238-246},
journal = {Comptes Rendus Mécanique}}

@article{AR-CFD-12-20909,
author = {Franzelli, B. and Riber, E. and Gicquel, L.Y.M. and Poinsot, Th. },
title = {Large Eddy Simulation of combustion instabilities in a lean partially premixed swirled flame},
year = {2012},
number = {2},
volume = {159},
pages = {621 - 637},
journal = {cf},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_11_4.pdf}}

@ARTICLE{AR-CFD-10-20906,
author = {Franzelli, B. and Riber, E. and Sanjosé, M. and Poinsot, Th. },
title = {A two-step chemical scheme for Large Eddy Simulation of kerosene-air flames},
year = {2010},
number = {7},
volume = {157},
pages = {1364 - 1373},
journal = {Combustion and Flame},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_09_86.pdf}}

@article{AR-CFD-09-21599,
author = {Senoner, J.-M. and Sanjosé, M. and Lederlin, T. and Jaegle, F. and Garcia, M. and Riber, E. and Cuenot, B. and Gicquel, L.Y.M. and Pitsch, H. and Poinsot, Th. },
title = {Eulerian and lagrangian large-eddy simulations of an evaporating two-phase flow},
year = {2009},
number = {6-7},
volume = {337},
pages = {458 - 468},
journal = {Comptes Rendus de l’Académie des Sciences – Mécanique},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_09_29.pdf}}

@article{AR-CFD-09-21465,
author = {Riber, E. and Moureau, V. and Garcia, M. and Poinsot, Th. and Simonin, O. },
title = {Evaluation of numerical strategies for Large Eddy Simulation of particulate two-phase recirculating flows},
year = {2009},
number = {2},
volume = {228},
pages = {539 - 564},
journal = {Journal of Computational Physics},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_09_17.pdf}}

@ARTICLE{AR-CFD-08-20597,
author = {Boileau, M. and Pascaud, S. and Riber, E. and Cuenot, B. and Gicquel, L.Y.M. and Poinsot, Th. and Cazalens, M. },
title = {Investigation of two-fluid methods for Large Eddy Simulation of spray combustion in Gas Turbines},
year = {2008},
number = {3},
volume = {80},
pages = {291 - 321},
journal = {Flow Turbulence and Combustion},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_07_10.pdf}}

Felden, A., Esclapez, L., Misdariis, A., Riber, E., Cuenot, B. and Wang, H. (2017) Including real fuel chemistry in Large-Eddy Simulations, 7 TH European Conference for Aeronautics and Aerosp Sciences (EUCASS). Milan, Italy 2017, CD Felden, A., Jaravel, T., Riber, E., Cuenot, B. and Pepiot, P. (2016) Predicting pollutant emissions in complex burners using analytically reduced chemistry, MUSAF III. ONERA. Toulouse, France 2016 Felden, A., Riber, E. and Cuenot, B. (2016) Effect of the chemistry description on LES of a realistic swirled non-premixed combustor, 36th International Symposium on Combustion. Korean Section of the Combustion Institute. Seoul, Korea 2016 Jaravel, T., Riber, E., Cuenot, B. and Bulat, G. (2016) Large Eddy Simulation of a model gas turbine burner using reduced chemistry with accurate pollutant prediction, 36th International Symposium on Combustion. Korean Section of the Combustion Institute. Seoul, Korea 2016 Shum Kivan, F., Marrero-Santiago, J., Verdier, A., Riber, E., Renou, B., Cabot, G. and Cuenot, B. (2016) Experimental and numerical analysis of a turbulent spray flame structure, 36th International Symposium on Combustion. Korean Section of the Combustion Institute. Seoul, Korea 2016 Felden, A., Riber, E., Cuenot, B., Esclapez, L., Ihme, M. and Wang, H. (2016) Including real fuel chemistry in LES of turbulent combustion, Proceedings of the Summer Program 2016. Center for Turbulence Research. Stanford University, Palo Alto, USA 2016, p. 113-122 Lacassagne, L., Bridel-Bertomeu, T., Riber, E., Cuenot, B., Casalis, G. and Nicoud, F. (2016) Lateral blowing impact on corner vortex shedding in solid rocket motors, Space Propulsion 2016. Rome, Italy 2016, 3AF (Ed.), p. 20163125166 Riber, E. and Cuenot, B. (2015) Modeling production and transport of soot particles for Large Eddy Simulation - Invited conference, Journée scientifique INCA suies. Snecma Villaroche, France 2015 Franzelli, B., Riber, E., Cuenot, B. and Ihme, M. (2015) Numerical modeling of soot production in aero-engine combustors using Large Eddy Simulations, Asme turbo expo 2015: turbine technical conference and exposition. Montreal, Canada 2015 Bauerheim, M., Jaravel, T., Esclapez, L., Cazalens, M., Bourgois, S., Rullaud, M., Riber, E., Gicquel, L. and Cuenot, B. (2015) Multiphase flow LES study of the fuel split effects on combustion instabilities in an ultra low-NOx annular combustor, Asme turbo expo 2015: turbine technical conference and exposition. Montreal, Canada 2015 Shum Kivan, F., Cuenot, B. and Riber, E. (2015) Turbulent diffusion flame modelling in Large Eddy Simulation (LES), 15th International Conference on Numerical Combustion. Avignon, France 2015 Rochoux, M., Cuenot, B., Duchaine, F., Riber, E., Veynante, D. and Darabiha, N. (2015) Analysis of large-eddy simulations of laboratory-scale fire, 15th International Conference on Numerical Combustion. Avignon, France 2015 Esclapez, L., Riber, E. and Cuenot, B. (2015) A statistical model to predict ignition probability, 15th International Conference on Numerical Combustion. Avignon, France 2015 Franzelli, B., Riber, E., Cuenot, B. and Ihme, M. (2015) Sensitivity of soot production to gaseous kinetic models in LES of aero-engine combustors, 15th International Conference on Numerical Combustion. Avignon, France 2015 Zhu, M., Riber, E., Cuenot, B., Bodart, J. and Poinsot, T. (2014) Wall-resolved Large Eddy Simulation in refinery ribbed pipes, Proceedings of the 2014 summer program. Center for Turbulence Research, NASA AMES, Stanford University, USA 2014 Cuenot, B., Riber, E. and Franzelli, B. (2014) Towards the prediction of soot in aero-engine combustors with Large Eddy Simulation, Proceedings of the 2014 summer program. Center for Turbulence Research, NASA AMES, Stanford University, USA 2014 Riber, E. (2014) Large Eddy Simulation of aeroengines fueled by airblast injectors - invited conference, Investigation of assisted atomization in industrial application workshop. ONERA TOULOUSE, France 2014 Chaussonnet, G., Riber, E., Vermorel, O., Cuenot, B., Gepperth, S. and Koch, R. (2013) Large eddy simulation of a prefilming airblast atomizer, 25th european conference on liquid atomization and spray systems. Chania, Greece 2013 Paulhiac, D., Riber, E. and Cuenot, B. (2013) Large Eddy Simulation of a lab-scale spray burner, ILASS Europe 2013, 25th European Conference. Chania, Greece, 9 2013 Cuenot, B., Gicquel, L. Y. M., Riber, E., Staffelbach, G., Vermorel, O., Dauptain, A., Duchaine, F. and Poinsot, T. (2013) Simulations aux Grandes Echelles: instabilités thermo-acoustiques, combustion diphasique et couplages multi-physiques - invited conference, 21 ième congrès français de mécanique - bordeaux, france. 2013 Cordier, M., Vandel, A., Renou, B., Cabot, G., Boukhalfa, M. A., Esclapez, L., Barré, D., Riber, E., Cuenot, B. and Gicquel, L. Y. M. (2013) Experimental and numerical analysis of an ignition sequence in a multiple-injectors burner, Asme turbo expo 2013. San Antonio, Texas, USA 2013 Gicquel, L. Y. M., Cuenot, B., Staffelbach, G., Vermorel, O., Riber, E., Dauptain, A. and Poinsot, T. (2013) Simulation en combustion diphasique turbulente: codes, formation, diffusion chez les industriels, calculs HPC - GENCI, PRACE, INCITE - invited conference, JOURNÉE CFD EQUIP@MESO 2013. CORIA. UNIVERSITE DE ROUEN, 5 2013 Rochoux, M., Cuenot, B., Riber, E., Veynante, D. and Darabiha, N. (2013) Turbulent combustion simulations of a laboratory-scale fire propagation, Numerical Simulation of Forest Fires, from Combustion to Emissions. Cargèse, France, 5 2013 Trouvé, A., Cuenot, B. and Riber, E. (2012) Numerical modeling of the deposition of combustion-generated soot particles on cold wall surfaces, Proceedings of the 2012 summer program. Center for Turbulence Research, NASA AMES, Stanford University, USA 2012, p. 419-428 Gicquel, L. Y. M., Cuenot, B., Staffelbach, G., Vermorel, O., Riber, E., Dauptain, A., Duchaine, F., Gourdain, N., Sicot, F. and Poinsot, T. (2012) CERFACS state-of-the-art and recent investigations for temperature predictions in turbo-machineries - invited conference, Conference on high fidelity simulations of combustion turbine systems. GE RC Niskayuna, NY, USA 2012 Masi, E., Sierra, P., Simonin, O., Riber, E. and Gicquel, L. Y. M. (2012) Algebraic-closure-based moment method for unsteady eulerian simulation of particle-laden turbulent flows in very dilute regime and high stokes numbers - Invited plenary conference, International conference on numerical methods in multiphase flow - invited plenary conference. The Pennsylvania State University, USA 2012 Riber, E., Cuenot, B. and Gicquel, L. Y. M. (2012) Utilisation de la Simulation aux Grandes Echelles (LES) pour la prédiction de l'allumage et de la probabilité d'allumage dans les chambres de combustion - invited conference, Journée thématique du GFC : procédés d'allumage. 5 Avril 2012, IFPEN, Rueil-Malmaison, France 2012 Hannebique, G., Riber, E. and Cuenot, B. (2012) Structure de flamme diphasique euler/lagrange dans la chambre MERCATO, Crct 2012. Cerfacs, Toulouse France 2012 Riber, E., Cuenot, B. and Gicquel, L. Y. M. (2012) Utilisation de la Simulation aux Grandes Echelles (LES) pour la prédiction de l'allumage et de la probabilité d'allumage dans les chambres de combustion aéronautiques, Journée thématique du GFC : procédés d'allumage. IFPEN, Rueil-Malmaison, France 2012 Lecocq, G., Hernandez-Vera, I., Poitou, D., Riber, E. and Cuenot, B. (2011) Soot prediction by Large-Eddy Simulation of complex geometry combustion chambers, 3ème colloque inca. ONERA, Toulouse 2011 Hannebique, G., Riber, E. and Cuenot, B. (2011) Ignition probability from Lagrangian computations in the MERCATO bench: comparison with Eulerian simulations, 3ème colloque inca. ONERA Toulouse 2011 Hernandez-Vera, I., Lecocq, G., Poitou, D., Riber, E. and Cuenot, B. (2011) Computations of soot formation in ethylene/air counterflow diffusion flames and its interaction with radiation, 3ème colloque inca. ONERA Toulouse 2011 Dauptain, A., Frichet, G., Duchaine, F., Riber, E., Dejean, G. and Poinsot, T. (2011) Transferring Large Eddy Simulation tools from laboratories experts to industry users: a challenge for the INCA community, 3ème colloque inca. ONERA Toulouse, France 2011 Auzillon, P., Riber, E., Gicquel, L. Y. M., Gicquel, O., Darabiha, N., Veynante, D. and Fiorina, B. (2011) Numerical investigation of a helicopter combustion chamber using LES and tabulated chemistry, 3ème colloque INCA. ONERA Toulouse 2011 Hannebique, G., Sierra, P., Riber, E. and Cuenot, B. (2011) Large Eddy Simulation of reactive two-phase flow in aeronautical multipoint burner, 7th mediterranean combustion symposium - september 11-15. Chia Laguna, Cagliari, Sardinia, Italy 2011 Gicquel, L. Y. M., Cuenot, B., Staffelbach, G., Vermorel, O., Riber, E., Dauptain, A., Duchaine, F. and Poinsot, T. (2011) LES modeling and sensitivity issues - implications on the prediction and flame dynamics - invited conference, Ge global research symposium on LES of turbulent reacting flows for GT design. Niskayuna, NY, USA 2011 Gicquel, L. Y. M., Cuenot, B., Staffelbach, G., Vermorel, O., Riber, E., Dauptain, A. and Poinsot, T. (2011) Panel session 4-34 - LES modeling of combustors: CERFACS perspective - invited conference, Asme turbo-expo. Vancouver, Canada 2011 Franzelli, B., Riber, E. and Cuenot, B. (2011) Impact of the chemical description on a Large Eddy Simulation of a lean partially premixed swirled flame, 3ème colloque inca. ONERA Toulouse, France 2011 Dauptain, A., Frichet, G., Duchaine, F., Riber, E., Dejean, G. and Poinsot, T. (2011) Transferring Large Eddy Simulation tools from laboratories expertsto industry users: a challenge for the inca community, Third workshop inca. ONERA Toulouse, France 2011 Masi, E., Riber, E., Sierra, P., Simonin, O. and Gicquel, L. Y. M. (2010) Modeling the random uncorrelated velocity stress tensor for unsteady particle eulerian simulation in turbulent flows, 7th international conference on multiphase flow. Tampa, Floride USA 2010 Gicquel, L. Y. M., Cuenot, B., Staffelbach, G., Riber, E., Dauptain, A., Gourdain, N., Montagnac, M., Boussuge, J. -F., Gazaix, M. and Poinsot, T. (2010) High performance computing of industrial flows: application to aeronautic and propulsion challenges - invited conference, 1st workshop on Complex Fluid Dynamics. Kaust campus, Saudi Arabia 2010 Garcia, M., Riber, E., Simonin, O. and Poinsot, T. (2007) Comparison between euler/euler and euler/lagrange les approaches for confined bluff-body gas-solid flow, International conference on multiphase flow. Liepzig, Germany 2007 Cuenot, B., Boileau, M., Pascaud, S., Mossa, J. -B., Riber, E., Poinsot, T. and Bérat, C. (2006) Large Eddy Simulation of two-phase reacting flows, ECCOMAS CFD 2006. Egmond Aan Zee, The Netherlands, 9 2006, CD-ROM (session 474), p. 1-19, ISBN 90-9020970-0 Riber, E., Garcia, M., Moureau, V., Pitsch, H., Simonin, O. and Poinsot, T. (2006) Evaluation of numerical strategies for LES of two-phase reacting flows, Proceedings of the summer program. Center for Turbulence Research, NASA AMES, Stanford University, USA 2006, p. 197-211 Riber, E., Moreau, M., Simonin, O. and Cuenot, B. (2006) Development of Euler-Euler LES approach for gas-particle turbulent jet flow, Asme - 2nd joint u.s.-european fluids engineering summer meeting collocated with the 14th international conference on nuclear engineering (fedsm2006). Miami, Florida - USA 2006 Riber, E., Moreau, M., Simonin, O. and Cuenot, B. (2005) Towards Large Eddy Simulation of non-homogeneous particle laden turbulent gas flows using euler-euler approach, 11th workshop on two-phase flow predictions. Merseburg, Germany 2005

@CONFERENCE{PR-CFD-17-100,
author = {Felden, A. and Esclapez, L. and Misdariis, A. and Riber, E. and Cuenot, B. and Wang, H. },
title = {Including real fuel chemistry in Large-Eddy Simulations},
year = {2017},
booktitle = {7 TH European Conference for Aeronautics and Aerosp Sciences (EUCASS)},
volume = {CD},
address = {Milan, Italy},
abstract = {Large-eddy simulation (LES) is progressively becoming a crucial design tool for the next generation of
aeronautical combustion chambers. However, further improvements of the capability of LES is required
for predicting pollutant emissions. Indeed, the detailed description of fuel pyrolysis and oxidation requires
to take into account hundreds of chemical species involved in the complex non-linear reaction process.
The direct integration of such detailed chemistry in LES is not a viable path, because of excessive compu-
tational demands and numerical stiffness. Modeling real transportation fuel is further complicated by the
fact that kerosenes are complex blends of a large number of hydrocarbon compounds; the exact composi-
tion of which is very difficult to determine. In this work, the real-fuel combustion chemistry is described
by the Hybrid Chemistry (HyChem) approach; and an LES-compliant Analytically Reduced Chemistry
(ARC) is used to allow a direct integration of the fuel chemistry in the LES solver. The ARC mecha-
nism is coupled with the Dynamically Thickened Flame LES model (DTFLES) and a Lagrangian spray
description to investigate the turbulent two-phase flow flame of a lean direct injection combustor, fueled
with Jet-A. The LES results are compared to experimental data in terms of gas velocity, temperature and
major species (CO2, H2O, CO, NO) mass fractions. It is found that the proposed methodology accurately
predicts both the flow dynamics and pollutant formation, and presents therefore a great potential to study
complex flame configurations burning real jet fuels},
pdf = {http://cerfacs.fr/wp-content/uploads/2017/06/CFD_FELDEN_EUCASS2017.pdf}}

@CONFERENCE{PR-CFD-16-327,
author = {Felden, A. and Jaravel, T. and Riber, E. and Cuenot, B. and Pepiot, P. },
title = {Predicting pollutant emissions in complex burners using analytically reduced chemistry},
year = {2016},
booktitle = {MUSAF III},
organization = {ONERA },
address = {Toulouse, France},
url = {http://musaf2016.onera.fr/sites/musaf2016.onera.fr/files/combustion_4_riber.pdf}}

@CONFERENCE{PR-CFD-16-191,
author = {Felden, A. and Riber, E. and Cuenot, B. },
title = {Effect of the chemistry description on LES of a realistic swirled non-premixed combustor},
year = {2016},
booktitle = {36th International Symposium on Combustion},
organization = {Korean Section of the Combustion Institute},
address = {Seoul, Korea}}

@CONFERENCE{PR-CFD-16-193,
author = {Jaravel, T. and Riber, E. and Cuenot, B. and Bulat, G. },
title = {Large Eddy Simulation of a model gas turbine burner using reduced chemistry with accurate pollutant prediction},
year = {2016},
booktitle = {36th International Symposium on Combustion},
organization = {Korean Section of the Combustion Institute},
address = {Seoul, Korea}}

@CONFERENCE{PR-CFD-16-195,
author = {Shum Kivan, F. and Marrero-Santiago, J. and Verdier, A. and Riber, E. and Renou, B. and Cabot, G. and Cuenot, B. },
title = {Experimental and numerical analysis of a turbulent spray flame structure},
year = {2016},
booktitle = {36th International Symposium on Combustion},
organization = {Korean Section of the Combustion Institute},
address = {Seoul, Korea}}

@CONFERENCE{PR-CFD-16-242,
author = {Felden, A. and Riber, E. and Cuenot, B. and Esclapez, L. and Ihme, M. and Wang, H. },
title = {Including real fuel chemistry in LES of turbulent combustion},
year = {2016},
booktitle = {Proceedings of the Summer Program 2016},
pages = {113-122},
organization = {Center for Turbulence Research},
address = {Stanford University, Palo Alto, USA},
abstract = {Large Eddy Simulation (LES) of an aeronautical burner is performed with two combustion models and a reduced chemical scheme, able to accurately describe the combustion of a real multi-component kerosene aviation fuel. The accuracy of the reduced scheme is first assessed on laminar flame cases through comparison with detailed chemistry mechanism. Subsequently, the chemical mechanism is employed in 3D simulations, demonstrating its ability to correctly predict combustion chemistry in turbulent flames.
},
pdf = {http://cerfacs.fr/wp-content/uploads/2017/01/CFD_CTR2016_Felden.pdf}}

@CONFERENCE{PR-CFD-16-222,
author = {Lacassagne, L. and Bridel-Bertomeu, T. and Riber, E. and Cuenot, B. and Casalis, G. and Nicoud, F. },
title = {Lateral blowing impact on corner vortex shedding in solid rocket motors},
year = {2016},
booktitle = {Space Propulsion 2016},
editor = {3AF},
pages = {20163125166},
address = {Rome, Italy},
abstract = {: The corner vortex shedding in solid rocket motors also called VSA is studied in an academic configuration with compressible unsteady simulation and linear stability analysis. Lateral blowing impact on the stability of the flow is analysed thanks to parametric unsteady simulations by varying the flow rate over the upper surface. The results clearly show a stabilization of the flow when lateral blowing increases. Linear stability analysis on local velocity profiles enables to accurately reconstruct the mode on a selected weakly unstable case, although the frequency selection mechanism is not well captured. The same analysis is performed on a stable case and even if strong differences are noticed, linear stability do not give a conclusion as clear as the one obtained with numerical simulations. More generally, these results show a stabilization effect of the lateral blowing on corner vortex shedding and the ability of the linear stability analysis to reproduce and predict this mechanism},
keywords = {Corner vortex shedding ; solid rocket motors ; large eddy simulation ; linear stability},
pdf = {http://cerfacs.fr/wp-content/uploads/2017/06/CFD_CONFSpacePro16_Lacassagne.pdf}}

@CONFERENCE{PR-CFD-15-26898,
author = {Riber, E. and Cuenot, B. },
title = {Modeling production and transport of soot particles for Large Eddy Simulation - Invited conference},
year = {2015},
address = {Snecma Villaroche, France},
booktitle = {Journée scientifique INCA suies}}

@conference{PR-CFD-15-23297,
author = {Franzelli, B. and Riber, E. and Cuenot, B. and Ihme, M. },
title = {Numerical modeling of soot production in aero-engine combustors using Large Eddy Simulations},
year = {2015},
pages = {},
address = {Montreal, Canada},
booktitle = {Asme turbo expo 2015: turbine technical conference and exposition}}

@CONFERENCE{PR-CFD-15-23157,
author = {Bauerheim, M. and Jaravel, T. and Esclapez, L. and Cazalens, M. and Bourgois, S. and Rullaud, M. and Riber, E. and Gicquel, L. and Cuenot, B. },
title = {Multiphase flow LES study of the fuel split effects on combustion instabilities in an ultra low-NOx annular combustor},
year = {2015},
booktitle = {Asme turbo expo 2015: turbine technical conference and exposition},
address = {Montreal, Canada}}

@CONFERENCE{PR-CFD-15-26900,
author = {Shum Kivan, F. and Cuenot, B. and Riber, E. },
title = {Turbulent diffusion flame modelling in Large Eddy Simulation (LES)},
year = {2015},
address = { Avignon, France},
booktitle = {15th International Conference on Numerical Combustion}}

@CONFERENCE{PR-CFD-15-26902,
author = {Rochoux, M. and Cuenot, B. and Duchaine, F. and Riber, E. and Veynante, D. and Darabiha, N. },
title = {Analysis of large-eddy simulations of laboratory-scale fire},
year = {2015},
address = {Avignon, France},
booktitle = {15th International Conference on Numerical Combustion}}

@CONFERENCE{PR-CFD-15-26905,
author = {Esclapez, L. and Riber, E. and Cuenot, B. },
title = {A statistical model to predict ignition probability},
year = {2015},
address = {Avignon, France},
booktitle = {15th International Conference on Numerical Combustion}}

@CONFERENCE{PR-CFD-15-26907,
author = {Franzelli, B. and Riber, E. and Cuenot, B. and Ihme, M. },
title = {Sensitivity of soot production to gaseous kinetic models in LES of aero-engine combustors},
year = {2015},
booktitle = {15th International Conference on Numerical Combustion},
address = {Avignon, France}}

@conference{PR-CFD-14-23589,
author = {Zhu, M. and Riber, E. and Cuenot, B. and Bodart, J. and Poinsot, Th. },
title = {Wall-resolved Large Eddy Simulation in refinery ribbed pipes},
year = {2014},
address = {Center for Turbulence Research, NASA AMES, Stanford University, USA},
booktitle = {Proceedings of the 2014 summer program}}

@conference{PR-CFD-14-23230,
author = {Cuenot, B. and Riber, E. and Franzelli, B. },
title = {Towards the prediction of soot in aero-engine combustors with Large Eddy Simulation},
year = {2014},
address = {Center for Turbulence Research, NASA AMES, Stanford University, USA},
booktitle = {Proceedings of the 2014 summer program}}

@conference{PR-CFD-14-23502,
author = {Riber, E. },
title = {Large Eddy Simulation of aeroengines fueled by airblast injectors - invited conference},
year = {2014},
address = {ONERA TOULOUSE, France},
booktitle = {Investigation of assisted atomization in industrial application workshop}}

@conference{PR-CFD-13-23197,
author = {Chaussonnet, G. and Riber, E. and Vermorel, O. and Cuenot, B. and Gepperth, S. and Koch, R. },
title = {Large eddy simulation of a prefilming airblast atomizer},
year = {2013},
address = {Chania, Greece},
booktitle = {25th european conference on liquid atomization and spray systems},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_13_59.pdf}}

@CONFERENCE{PR-CFD-13-2,
author = {Paulhiac, D. and Riber, E. and Cuenot, B. },
title = {Large Eddy Simulation of a lab-scale spray burner},
year = {2013},
month = {9},
booktitle = {ILASS Europe 2013, 25th European Conference},
address = {Chania, Greece}}

@conference{PR-CFD-13-23224,
author = {Cuenot, B. and Gicquel, L.Y.M. and Riber, E. and Staffelbach, G. and Vermorel, O. and Dauptain, A. and Duchaine, F. and Poinsot, Th. },
title = {Simulations aux Grandes Echelles: instabilités thermo-acoustiques, combustion diphasique et couplages multi-physiques - invited conference},
year = {2013},
booktitle = {21 ième congrès français de mécanique - bordeaux, france},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_13_68.pdf}}

@conference{PR-CFD-13-23203,
author = {Cordier, M. and Vandel, A. and Renou, B. and Cabot, G. and Boukhalfa, M.A. and Esclapez, L. and Barré, D. and Riber, E. and Cuenot, B. and Gicquel, L.Y.M. },
title = {Experimental and numerical analysis of an ignition sequence in a multiple-injectors burner},
year = {2013},
address = {San Antonio, Texas, USA},
booktitle = {Asme turbo expo 2013}}

@CONFERENCE{PR-CFD-13-4,
author = {Gicquel, L.Y.M. and Cuenot, B. and Staffelbach, G. and Vermorel, O. and Riber, E. and Dauptain, A. and Poinsot, T. },
title = {Simulation en combustion diphasique turbulente: codes, formation, diffusion chez les industriels, calculs HPC - GENCI, PRACE, INCITE - invited conference},
year = {2013},
month = {5},
booktitle = {JOURNÉE CFD EQUIP@MESO 2013},
organization = {CORIA},
address = { UNIVERSITE DE ROUEN},
abstract = {Dans le cadre des actions d'animation scientifique de l'équipement d'excellence Equip@meso, un colloque intitulé "Mécanique des fluides numérique intensive : méthodes et nouvelles applications" est organisé, le 16 mai 2013, au CRIHAN (salle de conférence du CORIA ou amphithéâtre de l'Université de Rouen en fonction du nombre d'inscrits). Méthodes de calcul haute performance et nouveaux enjeux scientifiques seront présentés par des chercheurs en mécanique des fluides, utilisateurs des mésocentres Equip@meso},
url = {http://equipameso-cfd2013.crihan.fr/doku.php?id=resumecerfacs}}

@CONFERENCE{PR-CMGC-13-13,
author = {Rochoux, M. and Cuenot, B. and Riber, E. and Veynante, D. and Darabiha, N. },
title = {Turbulent combustion simulations of a laboratory-scale fire propagation},
year = {2013},
month = {5},
booktitle = {Numerical Simulation of Forest Fires, from Combustion to Emissions},
address = {Cargèse, France}}

@conference{PR-CFD-12-23564,
author = {Trouvé, A. and Cuenot, B. and Riber, E. },
title = {Numerical modeling of the deposition of combustion-generated soot particles on cold wall surfaces},
year = {2012},
pages = {419 - 428},
address = {Center for Turbulence Research, NASA AMES, Stanford University, USA},
booktitle = {Proceedings of the 2012 summer program},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_12_75.pdf}}

@conference{PR-CFD-12-23326,
author = {Gicquel, L.Y.M. and Cuenot, B. and Staffelbach, G. and Vermorel, O. and Riber, E. and Dauptain, A. and Duchaine, F. and Gourdain, N. and Sicot, F. and Poinsot, Th. },
title = {CERFACS state-of-the-art and recent investigations for temperature predictions in turbo-machineries - invited conference},
year = {2012},
address = {GE RC Niskayuna, NY, USA},
booktitle = {Conference on high fidelity simulations of combustion turbine systems},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_12_44.pdf}}

@CONFERENCE{PR-CFD-12-23412,
author = {Masi, E. and Sierra, P. and Simonin, O. and Riber, E. and Gicquel, L.Y.M. },
title = {Algebraic-closure-based moment method for unsteady eulerian simulation of particle-laden turbulent flows in very dilute regime and high stokes numbers - Invited plenary conference},
year = {2012},
address = {The Pennsylvania State University, USA},
booktitle = {International conference on numerical methods in multiphase flow - invited plenary conference}}

@CONFERENCE{PR-CFD-12-26888,
author = {Riber, E. and Cuenot, B. and Gicquel, L.Y.M. },
title = {Utilisation de la Simulation aux Grandes Echelles (LES) pour la prédiction de l'allumage et de la probabilité d'allumage dans les chambres de combustion - invited conference},
year = {2012},
booktitle = {Journée thématique du GFC : procédés d'allumage},
address = {5 Avril 2012, IFPEN, Rueil-Malmaison, France}}

@conference{PR-CFD-12-23353,
author = {Hannebique, G. and Riber, E. and Cuenot, B. },
title = {Structure de flamme diphasique euler/lagrange dans la chambre MERCATO},
year = {2012},
address = {Cerfacs, Toulouse France},
booktitle = {Crct 2012},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_12_21.pdf}}

@CONFERENCE{PR-CFD-12-26909,
author = {Riber, E. and Cuenot, B. and Gicquel, L.Y.M. },
title = {Utilisation de la Simulation aux Grandes Echelles (LES) pour la prédiction de l'allumage et de la probabilité d'allumage dans les chambres de combustion aéronautiques},
year = {2012},
booktitle = {Journée thématique du GFC : procédés d'allumage},
address = {IFPEN, Rueil-Malmaison, France}}

@conference{PR-CFD-11-23395,
author = {Lecocq, G. and Hernandez-Vera, I. and Poitou, D. and Riber, E. and Cuenot, B. },
title = {Soot prediction by Large-Eddy Simulation of complex geometry combustion chambers},
year = {2011},
address = {ONERA, Toulouse},
booktitle = {3ème colloque inca},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_11_105.pdf}}

@conference{PR-CFD-11-23352,
author = {Hannebique, G. and Riber, E. and Cuenot, B. },
title = {Ignition probability from Lagrangian computations in the MERCATO bench: comparison with Eulerian simulations},
year = {2011},
address = {ONERA Toulouse},
booktitle = {3ème colloque inca}}

@conference{PR-CFD-11-23356,
author = {Hernandez-Vera, I. and Lecocq, G. and Poitou, D. and Riber, E. and Cuenot, B. },
title = {Computations of soot formation in ethylene/air counterflow diffusion flames and its interaction with radiation},
year = {2011},
address = {ONERA Toulouse},
booktitle = {3ème colloque inca},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_11_107.pdf}}

@conference{PR-CFD-11-23240,
author = {Dauptain, A. and Frichet, G. and Duchaine, F. and Riber, E. and Dejean, G. and Poinsot, Th. },
title = {Transferring Large Eddy Simulation tools from laboratories experts to industry users: a challenge for the INCA community},
year = {2011},
address = {ONERA Toulouse, France},
booktitle = {3ème colloque inca},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_11_112.pdf}}

@CONFERENCE{PR-CFD-11-23151,
author = {Auzillon, P. and Riber, E. and Gicquel, L.Y.M. and Gicquel, O. and Darabiha, N. and Veynante, D. and Fiorina, B. },
title = {Numerical investigation of a helicopter combustion chamber using LES and tabulated chemistry},
year = {2011},
address = {ONERA Toulouse},
booktitle = {3ème colloque INCA}}

@conference{PR-CFD-11-23351,
author = {Hannebique, G. and Sierra, P. and Riber, E. and Cuenot, B. },
title = {Large Eddy Simulation of reactive two-phase flow in aeronautical multipoint burner},
year = {2011},
address = {Chia Laguna, Cagliari, Sardinia, Italy},
booktitle = {7th mediterranean combustion symposium - september 11-15},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_11_36.pdf}}

@conference{PR-CFD-11-23325,
author = {Gicquel, L.Y.M. and Cuenot, B. and Staffelbach, G. and Vermorel, O. and Riber, E. and Dauptain, A. and Duchaine, F. and Poinsot, Th. },
title = {LES modeling and sensitivity issues - implications on the prediction and flame dynamics - invited conference},
year = {2011},
address = {Niskayuna, NY, USA},
booktitle = {Ge global research symposium on LES of turbulent reacting flows for GT design}}

@conference{PR-CFD-11-23323,
author = {Gicquel, L.Y.M. and Cuenot, B. and Staffelbach, G. and Vermorel, O. and Riber, E. and Dauptain, A. and Poinsot, Th. },
title = {Panel session 4-34 - LES modeling of combustors: CERFACS perspective - invited conference},
year = {2011},
address = {Vancouver, Canada},
booktitle = {Asme turbo-expo},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_11_52.pdf}}

@conference{PR-CFD-11-20908,
author = {Franzelli, B. and Riber, E. and Cuenot, B. },
title = {Impact of the chemical description on a Large Eddy Simulation of a lean partially premixed swirled flame},
year = {2011},
address = {ONERA Toulouse, France},
booktitle = {3ème colloque inca},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_11_104.pdf}}

@CONFERENCE{PR-CFD-11-21961,
author = {Dauptain, A. and Frichet, G. and Duchaine, F. and Riber, E. and Dejean, G. and Poinsot, T. },
title = {Transferring Large Eddy Simulation tools from laboratories expertsto industry users: a challenge for the inca community},
year = {2011},
booktitle = {Third workshop inca},
address = {ONERA Toulouse, France}}

@conference{PR-CFD-10-23411,
author = {Masi, E. and Riber, E. and Sierra, P. and Simonin, O. and Gicquel, L.Y.M. },
title = {Modeling the random uncorrelated velocity stress tensor for unsteady particle eulerian simulation in turbulent flows},
year = {2010},
address = {Tampa, Floride USA},
booktitle = {7th international conference on multiphase flow},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_10_147.pdf}}

@CONFERENCE{PR-CFD-10-23319,
author = {Gicquel, L.Y.M. and Cuenot, B. and Staffelbach, G. and Riber, E. and Dauptain, A. and Gourdain, N. and Montagnac, M. and Boussuge, J.-F. and Gazaix, M. and Poinsot, Th. },
title = {High performance computing of industrial flows: application to aeronautic and propulsion challenges - invited conference},
year = {2010},
address = {Kaust campus, Saudi Arabia},
booktitle = {1st workshop on Complex Fluid Dynamics},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_10_21.pdf}}

@conference{PR-CFD-07-23307,
author = {Garcia, M. and Riber, E. and Simonin, O. and Poinsot, Th. },
title = {Comparison between euler/euler and euler/lagrange les approaches for confined bluff-body gas-solid flow},
year = {2007},
pages = {},
address = {Liepzig, Germany},
booktitle = {International conference on multiphase flow},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_07_80.pdf}}

@CONFERENCE{PR-CFD-06-1,
author = {Cuenot, B. and Boileau, M. and Pascaud, S. and Mossa, J.-B. and Riber, E. and Poinsot, T. and Bérat, C. },
title = {Large Eddy Simulation of two-phase reacting flows},
year = {2006},
month = {9},
booktitle = {ECCOMAS CFD 2006},
volume = {CD-ROM },
number = {session 474},
pages = {1-19},
isbn = { 90-9020970-0},
address = {Egmond Aan Zee, The Netherlands},
abstract = {Large Eddy Simulation (LES) is now recognized as an efficient numerical tool to predict gaseous combustion in industrial burners, and a number of examples of applications can be found in the literature. In these examples, the accuracy and the predictive capacity of LES are clearly demonstrated, even for unsteady phenomena. However most industrial burners are fed with liquid fuel and require the description of droplets dispersion, evaporation and burning. The presence of liquid fuel strongly modifies the fuel vapor distribution in the chamber, leading to different flame ignition and stabilisation processes, as well as different flame structures. Extending the LES technique to two-phase reacting flow is therefore crucial to capture and predict the behavior of such burners. This has been done in the code AVBP, coupling an eulerian solver for the liquid spray with a LES solver for the gas flow. This approach allows to work on unstructured grids and therefore to calculate the flow in complex geometries. In the present paper, the main steps of the extension of LES to two-phase flow are described and an example of validation is given. Then the solver is applied to the Vesta combustor of Turbomeca, composed of 18 main burners ignited by two pilot flames. This illustrates the capacity of LES to compute complex two-phase reacting flows in transient regimes. To demonstrate LES efficiency, some results will be shown for a calculation done on the IBM supercomputer BlueGene/L - cited by TOP500 as the world's fastest machine - where the use of 2048 parallel processors has enabled to start computing on the full combustor domain (i.e. 18 main injectors + 2 pilot flames).},
url = {http://proceedings.fyper.com/eccomascfd2006/}}

@conference{PR-CFD-06-21463,
author = {Riber, E. and Garcia, M. and Moureau, V. and Pitsch, H. and Simonin, O. and Poinsot, Th. },
title = {Evaluation of numerical strategies for LES of two-phase reacting flows},
year = {2006},
pages = {197 - 211},
address = {Center for Turbulence Research, NASA AMES, Stanford University, USA},
booktitle = {Proceedings of the summer program}}

@conference{PR-CFD-06-23500,
author = {Riber, E. and Moreau, M. and Simonin, O. and Cuenot, B. },
title = {Development of Euler-Euler LES approach for gas-particle turbulent jet flow},
year = {2006},
pages = {},
address = {Miami, Florida - USA},
booktitle = {Asme - 2nd joint u.s.-european fluids engineering summer meeting collocated with the 14th international conference on nuclear engineering (fedsm2006)}}

@conference{PR-CFD-05-23499,
author = {Riber, E. and Moreau, M. and Simonin, O. and Cuenot, B. },
title = {Towards Large Eddy Simulation of non-homogeneous particle laden turbulent gas flows using euler-euler approach},
year = {2005},
address = {Merseburg, Germany},
booktitle = {11th workshop on two-phase flow predictions},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_05_28.pdf}}

Gicquel, L. Y. M., Vermorel, O., Duchaine, F., Riber, E., Dauptain, A., Staffelbach, G., Cuenot, B. and Poinsot, T.. (2013) Gas Turbine and Industrial Burners. IN: Best Practice Guidelines in Computational Fluid Dynamics of Turbulent combustion. ERCOFTAC., 4

@BOOK{BK-CFD-13-3,
author = {Gicquel, L.Y.M. and Vermorel, O. and Duchaine, F. and Riber, E. and Dauptain, A. and Staffelbach, G. and Cuenot, B. and Poinsot, T. },
title = {Best Practice Guidelines in Computational Fluid Dynamics of Turbulent combustion},
year = {2013},
month = {2},
chaptertitle = {Gas Turbine and Industrial Burners},
publisher = {ERCOFTAC},
chapter = {4}}

Franzelli, B., Riber, E., Cuenot, B., Chen, J. H. and Richardson, E. (2014), Validity of reduced chemical modelling for numerical simulation of turbulent premixed flames, CERFACS, Toulouse, technical report Riber, E., Moureau, V., Garcia, M., Poinsot, T. and Simonin, O. (2007) 12 , Evaluation of numerical strategies for Large Eddy Simulation of particulate two-phase recirculating flows, Cerfacs, technical report Riber, E. (2003) 8 , Modélisation et calcul de jets diphasiques - rapport de DEA, Cerfacs, hydraulique et mécaniques des fluides - institut national polytechnique de toulouse Riber, E. (2003) 6 , Modélisation et calcul de jets diphasiques - rapport de fin d' études, Cerfacs, enseeiht

@TECHREPORT{TR-CFD-14-20911,
author = {Franzelli, B. and Riber, E. and Cuenot, B. and Chen, J.H. and Richardson, E. },
title = {Validity of reduced chemical modelling for numerical simulation of turbulent premixed flames},
year = {2014},
institution = {CERFACS, Toulouse},
type = {technical report}}

@TECHREPORT{TR-CFD-07-23501,
author = {Riber, E. and Moureau, V. and Garcia, M. and Poinsot, T. and Simonin, O. },
title = {Evaluation of numerical strategies for Large Eddy Simulation of particulate two-phase recirculating flows},
year = {2007},
institution = {Cerfacs},
month = {12},
type = {technical report},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_07_135.pdf}}

@techreport{TR-CFD-03-21462,
author = {Riber, E. },
title = {Modélisation et calcul de jets diphasiques - rapport de DEA},
year = {2003},
institution = {Cerfacs},
month = {8},
type = {hydraulique et mécaniques des fluides - institut national polytechnique de toulouse}}

@techreport{TR-CFD-03-21461,
author = {Riber, E. },
title = {Modélisation et calcul de jets diphasiques - rapport de fin d' études},
year = {2003},
institution = {Cerfacs},
month = {6},
type = {enseeiht},
url = {http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_03_72.pdf}}

Riber, E.. Développement de la méthode de simulation aux grandes échelles pour les écoulements diphasiques turbulents - th/cfd/07/41. Institut National Polytechnique de Toulouse, France -Dynamique des Fluides. (2007).

@phdthesis{TH-CFD-07-21464,
author = {Riber, E. },
title = {Développement de la méthode de simulation aux grandes échelles pour les écoulements diphasiques turbulents - th/cfd/07/41},
year = {2007},
school = {Institut National Polytechnique de Toulouse, France -Dynamique des Fluides},
url = {http://www.cerfacs.fr/~cfdbib/repository/TH_CFD_07_41.pdf}}