[30] Bayesian optimisation of RANS simulation with ensemble-based variational method in convergent-divergent channel, Xinlei Zhang, Thomas Gomez and Olivier Coutier-Delgosha, Journal of Turbulence, May 2019. DOI : 10.1080/14685248.2019.1622016
[29] « Magnetic control of flame stability: application to oxygen-enriched and carbondioxide-diluted sooting flames », A. Jocher, J. Bonnety, T. Gomez, H. Pitsch and G. Legros, Proceedings of The Combustion Institute, September 2018
[28] « Advanced spectral anisotropic modelling for shear flows, Journal of Turbulence », Antoine Briard, Benoît-Joseph Gréa, Vincent Mons, Claude Cambon, Thomas Gomez and Pierre Sagaut, , https://doi.org/10.1080/14685248.2018.1478092
[27] « The decay of isotropic magnetohydrodynamics turbulence and the effects of cross-helicity », Antoine Briard and Thomas Gomez, Journal of Plasma Physics, Feb 2018,
[26] « Closure theory for the split energy-helicity cascades in homogeneous isotropic homochiral turbulence », Antoine Briard, Luca Biferale and Thomas Gomez, Physical Review Fluids, Nov 2017
[25] « Combustion instability mitigation by magnetic fields », Agnes Jocher, Heinz Pitsch, Thomas Gomez, Jérôme Bonnety, and Guillaume Legros, Phys. Rev. E, Accepted31 May 2017
[24] « Dynamics of helicity in homogeneous skew-isotropic turbulence », Antoine Briard and Thomas Gomez, Journal of Fluid Mechanics, 821:539-581 · June 2017, DOI: 10.1017/jfm.2017.260
[23] Anisotropic spectral modeling for unstably stratified homogeneous turbulence, Antoine Briard, Manasa Iyer, and Thomas Gomez, Physical Review Fluids, 044604 (2017)
[22] Prandtl number effects in decaying homogeneous isotropic turbulence with a mean scalar gradient, Antoine Briard and Thomas Gomez, Journal of Turbulence 18(5):418-442 ·, February 2017, DOI: 10.1080/14685248.2017.1294253
[21] Mixed-derivative skewness for high Prandtl and Reynolds numbers in homogeneous isotropic turbulence, Antoine Briard and Thomas Gomez, Physics of Fluids 28(8):081703 · August 2016 DOI: 10.1063/1.4961255
[20] A. Jocher, J. Bonnety, H. Pitsch, T. Gomez, and G. Legros. Dual magnetic effects on soot production in partially premixed flames. Proceedings of the Combustion Institute, 2016, July 2016, DOI: 10.1016/j.proci.2016.05.017
[19] Briard, A., Gomez, T. and Cambon, C. (2016) ‘Spectral modelling for passive scalar dynamics in homogeneous anisotropic turbulence’, Journal of Fluid Mechanics, 799, pp. 159–199. doi: 10.1017/jfm.2016.362.
[18] A. Briard, T. Gomez, V. Mons, and P. Sagaut. Decay and growth laws in homogeneous shear turbulence. Journal of Turbulence, 17(7):699–726, 07 2016.
[17] V. Mons, J.-C. Chassaing, T. Gomez, P. Sagaut, Reconstruction of unsteady viscous flows using data assimilation schemes, Journal of Computational Physics, Volume 316, 1 July 2016, Pages 255-280
[16] “Modification of sooting tendency by magnetic effects“, A. Jocher · H. Pitsch · T. Gomez · G. Legros, Proceedings of the Combustion Institute, 35(1):889-895, Dec 2015
[15] “Passive scalar decay laws in isotropic turbulence: Prandtl number effects“. A. Briard, T. Gomez, P. Sagaut and S. Memari (2015). Journal of Fluid Mechanics, 784, pp 274-303
[14] A passive scalar convective-diffusive subrange for low Prandtl numbers in isotropic turbulence », A. Briard and T. Gomez, Phys. Rev. E, 91 (1) 011001, 2015.
[13] A. Jocher, H. Pitsch, T. Gomez, and G. Legros. Modulation of sooting tendency by magnetic effects, Proceedings of The Combustion Institute 35, 2015, DOI: 10.1016/j.proci.2014.05.139.
[12] Is isotropic turbulence decay governed by asymptotic behavior of large scales? An eddy-damped quasi-normal Markovian-based data assimilation study. Mons, V. and Chassaing, J.-C. and Gomez, T. and Sagaut, P., Physics of Fluids (1994-present), 26, 115105 (2014), DOI:http://dx.doi.org/10.1063/1.4901448
[11] G. Legros, T. Gomez, M. Fessard, T. Gouache, T. Ader, P. Guibert, P. Sagaut, and J.L. Torero. Magnetically induced flame flickering, Proceedings of The Combustion Institute 33, p.1095-1103, 2011.
[10] Stephane Monte, P. Sagaut, Th Gomez. Contribution of Reynolds stress distribution to the skin friction in compressible turbulent channel flows. Phys. Fluids 23, 065106 (2011).
[9] T. Gomez, V. Flutet, and P. Sagaut. Contribution of reynolds stress distribution to the skin friction in compressible turbulent channel flows. Physical Review E (Statistical, Nonlinear, and Soft Matter Physics), 79(3):035301–4, 03 2009.
[8] Gomez, T. Pseudo-wave decomposition high-order method for magnetogasdynamics. Journal of Computational Physics 227, 20 (2008), 8909–8921.
[7] Gomez, T., Sagaut, P., Schilling, O., and Zhou, Y. Large-eddy simulation of very large kinetic and magnetic reynolds number isotropic magnetohydrodynamic turbulence using a spectral subgrid model. Physics of Fluids 19, 4 (2007), 048101.
[6] Delbende, I., Gomez, T., Josserand, C., Nore, C., and Rossi, M. Various aspects of fluid vortices;. Comptes Rendus Mecanique 332, 9 (2004), 767–781.
[5] Politano, H., Gomez, T., and Pouquet, A. von kármán-howarth relationship for helical magnetohydrodynamic flows. Physical Review E 68, 2 (2003).
[4] Gomez, T., and Rossi, M. Instabilite d’une nappe de vorticite etiree instationnaireinstability of an unsteady stretched vortex layer;. Comptes Rendus Mecanique 331, 2 (2003), 141–147.
[3] Gomez, T., Politano, H., Pouquet, A., and Larcheveque, M. Spiral vortices in compressible turbulent flows. PHYSICS OF FLUIDS 13, 7 (Jul 2001), 2065–2075.
[2] Gomez, T., Politano, H., and Pouquet, A. Exact relationship for third-order structure functions in helical flows. PHYSICAL REVIEW E 61, 5 (May 2000), 5321–5325.
[1] Gomez, T., Politano, H., and Pouquet, A. On the validity of a nonlocal approach for mhd turbulence. PHYSICS OF FLUIDS 11, 8 (Aug 1999), 2298–2306.