User:Domingo

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Personal Information

Pascale Domingo

Pascale Domingo
Directrice de recherche CNRS

Office: INSA/Ma.B.R1
email: domingo@coria.fr
Tel: +33 (0)2 32 95 97 93

Lab Address

CORIA
Avenue de l'Université - BP 12
76801 Saint Etienne du Rouvray
Tel: +33 (0)2 32 95 97 93
Fax: +33 (0)2 32 95 97 82

Research Activities

  • Numerical Modelling of turbulent reactive flows

Teaching Activities

  • Direct and Large Eddy Simulation - INSA de Rouen (15 h)
  • Modélisation de la turbulence - Master EFE, Université de Rouen

Background

  • 1991: PhD University of Rouen
  • 1992: Post-Doc, Stanford Aeronautics and Astronautics department

Reviewing activities

  • Combustion and Flame, Journal of Fluid Mechanics, Physics of Fluids, Combustion Theory and Modeling, Flow Turbulence and Combustion,

AIAA Journal , Fuel, Combustion Science and Technology

Publications

  1. B. Farcy, L. Vervisch, P. Domingo, N. Perret (2016) Reduced-order modeling for the control of selective non-catalytic reduction (SNCR) of nitrogen monoxide, AIChE Journal, 62(3): 928-938..
  2. L. Cifuentes, C. Dopazo, J. Martin, C. Jimenez, P. Domingo, L. Vervisch (2016) Effects of the local flow topologies upon the structure of a premixed methane-air turbulent jet flame, Flow Turbulence and Combust., 96(2): 535-546.
  3. B. Farcy, L. Vervisch, P. Domingo (2016) Large Eddy Simulation of selective non-catalytic reduction (SNCR): A downsizing procedure for simulating nitric-oxide reduction units, Chemical Engineering Science, 139:285-303.
  4. A. Abou-Taouk, B. Farcy, P. Domingo, L. Vervisch, S. Sadasivuni, L.-E. Eriksson (2016) Optimized reduced chemistry and molecular transport for Large Eddy Simulation of partially premixed combustion in a gas turbine, Combust. Sci. Tech. 188(1): 21-39.
  5. G. Lodier, P. Domingo, L. Vervisch (2015) Quantification of the pre-ignition front propagation in DNS of rapidly compressed mixture, Flow. Turbulence and Combustion, 94(1): 219-235.
  6. L. Cifuentes, C. Dopazo, J. Martin, P. Domingo, L. Vervisch (2015) Local volumetric dilatation rate and scalar geometries in a premixed methane-air turbulent jet flame, Proc. Combust. Inst., 35(2): 1295-1303.
  7. P. Domingo, L. Vervisch (2015) Large Eddy Simulation of premixed turbulent combustion using approximate deconvolution and explicit flame filtering, Proc. Combust. Inst., 35(2): 1349-1357.
  8. X. Petit, G. Ribert, P. Domingo (2015) Framework for real-gas compressible reacting flows with tabulated thermochemistry, J. Supercritical Fluids (101).
  9. B. Farcy, A. Abou-Taouk, L. Vervisch, P. Domingo, N. Perret, (2014) Two approaches of chemistry downsizing for simulating Selective Non Catalytic Reduction DeNOx Process, Fuel, 118: 291-299,
  10. S. Nambully, P. Domingo, V. Moureau, L. Vervisch A Filtered-Laminar-Flame PDF sub-grid scale closure for LES of premixed turbulent flames. Part I: Formalism and application to a bluff-body burner with differential diffusion. Combust. Flame, 161(7): 1756-1774.
  11. S. Nambully, P. Domingo, V. Moureau, L. Vervisch A Filtered-Laminar-Flame PDF sub-grid scale closure for LES of premixed turbulent flames: Part II: Application to a stratified bluff-body burner, Combust. Flame, 161(7): 1775-1791.
  12. B. Farcy, A. Abou-Taouk, L. Vervisch, P. Domingo, N. Perret (2014) Two approaches of chemistry downsizing for simulating Selective Non Catalytic Reduction DeNOx Process, Fuel, 118: 291-299, DOI 10.1016/j.fuel.2013.10.070.
  13. G. Ribert, L. Vervisch, P. Domingo, Y.-S. Niu (2014) Hybrid transported-tabulated strategy to downsize detailed chemistry for numerical simulation of premixed flames, FLow Turbulence and Combustion, 92(1/2): 175-200. DOI 10.1007/s10494-013-9520-6.
  14. M. Belhi, P. Domingo, P. Vervisch (2013) Modeling of the Effect of DC and AC Electric Fields on the Stability of a Lifted Diffusion Methane/Air Flame, Combustion Theory and Modelling, 17(4), pp. 749-787(39)http://dx.doi.org/10.1080/13647830.2013.802415
  15. X. Petit, G. Ribert, P. Domingo, G. Lartigue (2013) Large-eddy simulation of supercritical fluid injection, J. Supercritical Fluids (84): 61 - 73. doi:10.1016/j.supflu.2013.09.011 link.
  16. C. Merlin, P. Domingo, L. Vervisch (2013) Immersed boundaries in Large Eddy Simulation of compressible flows, FLow Turbulence and Combustion, 90(1): 29-68 [1]
  17. C. Merlin, P. Domingo, L. Vervisch (2012) Large Eddy Simulation of turbulent flames in a Trapped Vortex Combustor (TVC) - A flamelet presumed-pdf closure preserving laminar flame speed Comptes Rendus Mécanique, 340 (11/12): 917-932. [2]
  18. G. Lodier, C. Merlin, P. Domingo, L. Vervisch, F. Ravet (2012) Self-ignition scenarios after rapid compression of a turbulent mixture weakly-stratified in temperature, Combust. Flame, 159(11), pp. 3358-3371. [3]
  19. N. Enjalbert, P. Domingo, L. Vervisch (2012) Mixing time-history effects in Large Eddy Simulation of non-premixed turbulent flames: Flow-Controlled Chemistry Tabulation, Combust. Flame 159(1), pp. 336-352.2012 [4]
  20. G. Lodier, L. Vervisch, V. Moureau, P. Domingo (2011) Composition-space premixed flamelet solution with differential diffusion for in situ flamelet-generated manifolds, Combust. Flame 158(10): 2009-2016. [5]
  21. V. Moureau, P. Domingo, L. Vervisch (2011) From Large-Eddy Simulation to Direct Numerical Simulation of a lean premixed swirl flame: Filtered Laminar Flame-PDF modeling, Combust. Flame 158(7): 1340-1357 [6]
  22. V. Moureau, P. Domingo, L. Vervisch (2011) Design of a massively parallel CFD code for complex geometries C.R. Mecanique 339(2/3): 141-148.
  23. K. Wang, G. Ribert, P. Domingo, L. Vervisch (2010) Self-similar behavior and chemistry tabulation of burnt-gases diluted premixed flamelets including heat-loss, Combust. Theory and Modelling 14(4): 541-570.
  24. M. Belhi, P. Domingo, P. Vervisch (2010) Direct numerical simulation of the effect of an electric field on flame stability , Combustion and Flame, 157(12): 2286-2297
  25. D. Veynante, G. Lodato, P. Domingo, L. Vervisch, E. R. Hawkes (2010) Estimation of three-dimensional flame surface densities from planar images in turbulent premixed combustion, Exp. in Fluids 49:267-278.
  26. L. Vervisch, P. Domingo, G. Lodato, D. Veynante (2010) Scalar energy fluctuations in Large-Eddy Simulation of turbulent flames: Statistical budgets and mesh quality criterion, Combust. Flame 157(4): 778-789.
  27. V. Subramanian, P. Domingo, L. Vervisch (2010) Large-Eddy Simulation of forced ignition of an annular bluff-body burner Combust. Flame 157(3): 579-601.
  28. P.-D. Nguyen, L. Vervisch, V. Subramanian, P. Domingo (2010) Multi-dimensional flamelet-generated manifolds for partially premixed combustion Combust. Flame 157(1): 43-61.
  29. G. Lodato, L. Vervisch, P. Domingo (2009) A compressible wall-adapting similarity mixed model for large-eddy simulation of the impinging round jet Phys. Fluids 21:035102.
  30. G. Godel, P. Domingo, L. Vervisch (2009) Tabulation of NOx chemistry for Large-Eddy Simulation of non-premixed turbulent flames Proc. Combust. Inst. 32: 1555-1551.
  31. D. Veynante, B. Fiorina, P. Domingo L. Vervisch, (2008) Using self-similar properties of turbulent premixed flames to downsize chemical tables in high-performance numerical simulations Combust. Theory and Modeling 12(6): 1055-1088.
  32. J. Galpin, A. Naudin, L. Vervisch, C. Angelberger, O. Colin, P. Domingo (2008) Large-Eddy Simulation of a fuel lean premixed turbulent swirl burner Combust. Flame 155(1): 247 266.
  33. G. Lodato, P. Domingo, L. Vervisch (2008) Three-dimensional boundary conditions for Direct and Large-Eddy Simulation of compressible flows J. of Comp. Phys. 227(10): 5105-5143.
  34. P. Domingo, L. Vervisch, D. Veynante (2008) Large-Eddy Simulation of a lifted methane jet flame in a vitiated coflow Combust. Flame 152(3): 415-432.
  35. P. Domingo, L. Vervisch (2007) DNS of partially premixed flame propagating in a turbulent rotating flow, Proceedings of the Combustion Institute, Vol. 31, pp 1657-1664.
  36. L. Vervisch, P. Domingo (2006) Two recent developments in numerical simulation of premixed and partially premixed turbulent flame, C. R. Mecanique, 334 (8/9), pp. 523-530.
  37. C. Péra, J. Réveillon, L. Vervisch, P. Domingo (2006) Modeling subgrid scale mixture fraction variance in LES of evaporating spray, Combustion and Flame, Vol.146(4).
  38. P. Domingo, L. Vervisch, S. Payet and R. Hauguel, (2005) DNS of a Premixed Turbulent V-Flame and LES of a Ducted-Flame using a FSD-PDF subgrid scale closure with FPI tabulated chemistry, Combustion and Flame}, 143(4), pp. 566-586.
  39. K.N.C. Bray, P. Domingo, L. Vervisch, (2005) The role of progress variable in models for partially premixed turbulent combustion, Combustion and Flame, 141(4), pp. 431-437.
  40. P. Domingo, L. Vervisch, J. R\'eveillon, (2005) DNS analysis of partially premixed combustion in spray and gaseous turbulent-flame bases stabilized in hot air, Combustion and Flame, 140(3), pp. 172-195.
  41. R. Hauguel, L. Vervisch, P. Domingo (2005) DNS of premixed turbulent V-Flame: coupling spectral and finite difference methods, C. R. Mecanique , 333 (1), pp.~95-102.
  42. L. Vervisch, R. Hauguel, P. Domingo, M. Rullaud (2004) Three facets of turbulent combustion modeling: DNS of premixed V-flame, LES of lifted nonpremixed flames and RANS of jet-flame, Journal of turbulence, 5(4), pp. 1-36.
  43. P. Domingo, L. Vervisch, K. N. C. Bray (2002) Partially premixed flamelets in LES of nonpremixed turbulent combustion, Combustion Theory and Modelling, 6(4), pp. 529-551.
  44. P. Domingo, K. N. C. Bray (2000) Laminar Flamelet expressions for pressure fluctuation terms in second moment models of premixed turbulent combustion, Combustion and Flame, Vol 121, pp 555-74.
  45. P. Domingo, T. Benazzouz (2000) Direct numerical simulation and modeling of a nonequilibrium turbulent plasma, AIAA Journal, Vol. 38, No. 1, pp. 73-78.
  46. A. Bourdon, A. Leroux, P. Domingo, P. Vervisch (1999) Experiment-modeling comparison in a nonequilibrium supersonic air nozzle flow, Journal of Thermophysics and Heat Tranfer, Vol. 13, No. 1, pp. 68-75.
  47. P. Domingo, L. Vervisch (1996) Triple flames and partially premixed combustion in autoignition of nonpremixed turbulent mixtures, Proceedings of the Combustion Institute}, pp. 223-240.
  48. L. Guichard, L. Vervisch, P. Domingo (1995) Two-dimensional weak-shock vortex interaction in a mixing zone, AIAA Journal, Vol 33, No 10, pp. 1797-802.
  49. P. Domingo, A. Bourdon, P. Vervisch (1995) Study of a low pressure nitrogen plasma jet", Physics of Plasmas, Vol. 2, no 7, pp. 2853-62.
  50. P. Domingo, D. Vandromme, P. Vervisch (1992) Modeling of an argon plasma in a boundary layer flow, Journal of thermophysics and heat transfer, Vol 6, No 2, pp. 217-23.

Ph.D. Graduates

- (*) indicates Ph.D. with co-advisor

  • Benjamin Farcy* «Analyse des mécanismes de destruction non catalytique des oxydes d'azote (DENOX) et application aux incinérateurs », 2015.
  • Lisa Bouhearouha* «Simulation aux grandes échelles de la combustion supersonique », 2014.
  • Xavier Petit* «Analyse de l’interaction cinétique chimique/turbulence dans une flamme cryotechnique LOX/CH4 », 2014.
  • Guillaume Lodier*, « Analyse de l'initiation et du développement de l'auto-inflammation après compression rapide d'un mélange turbulent réactif - Application au contexte CAI/HCCI », 2013.
  • Suresh Kumar Nambully*, "Accounting for differential diffusion effects in LES of turbulent combustion using a filtered laminar flame PDF approach. Application to stratified burners", 2013.
  • Memdouh Belhi «  Simulation Numérique de l’Effet de Champ Electrique sur la Stabilité des Flammes de Diffusion », 2012.
  • Cindy Merlin*, « Simulation numérique de la combustion turbulente : Méthode de frontières immergées pour les écoulements compressibles, application à la combustion en aval d’une cavité », 2011.
  • Nicolas Enjalbert*, « Modélisation avancée de la combustion turbulente diphasique en régime de forte dilution par les gaz brûlés », 2011.
  • Guillaume Godel*, « Modélisation de sous-maille de la combustion turbulente Développement d’outils pour la prédiction de la pollution dans une chambre aéronautique », 2010.
  • Vallinayagam Pillai Subramanian*, « Numerical simulation of forced ignition using LES coupled with a tabulated detailed chemistry approach », 2010.
  • Guido Lodato*, « Conditions aux limites tridimensionnelles pour la simulation directe et aux grandes échelles des écoulements turbulents. Modélisation de sous-maille pour la turbulence en région de proche paroi », 2008.
  • Alexandre Naudin*, « Simulation des grandes échelles de la combustion turbulente avec chimie détaillée tabulée », 2008.
  • Sandra Payet* « Analyse de l’oxy-combustion en régime dilué par simulation des grandes échelles », 2007.
  • Raphaël Hauguel* « Flamme en V turbulente, Simulation numérique directe et modélisation de la combustion turbulente prémélangée », 2003.
  • Tewfik Benazzouz «Modélisation numérique de plasmas en écoulement turbulent, application au cas de l'argon » 1999.
  • Alain Leroux « Modélisation d'écoulements supersoniques hors-équilibre chimique et thermique », 1997.
  • Anne Bourdon* « Les modélisations physiques d'un écoulement supersonique de plasma d'azote basse pression », 1995.