.. |br| raw:: html
.. _List-Of-Publications-with-LBM:
STMF Publications with LBM
==========================
.. container:: sphinx-features
.. admonition:: Two-phase in porous media
[P1]_ [P2]_ [P3]_ [P6]_ [P7]_
|br|
:math:`\hspace{3mm}`
.. admonition:: LBM for crystal growth
[P4]_ [P5]_ [p1]_ [T1]_ |br|
[R4]_ [R5]_ [R6]_ [R7]_
|br|
:math:`\hspace{3mm}`
.. admonition:: LBM for fractional ADE
[P8]_
:math:`\hspace{3mm}`
|br|
.. admonition:: Ternary Two-phase
[P9]_ [P11]_ [T2]_ [T3]_ |br|
[R9]_ [R11]_ [R12]_ [T4]_
:math:`\hspace{3mm}`
|br|
.. admonition:: Courses
[L1]_ [L2]_
.. container:: sphinx-features
.. admonition:: Dissolution
[P10]_
|br|
:math:`\hspace{3mm}`
.. admonition:: Single-phase NS
[R1]_ [R8]_
|br|
:math:`\hspace{3mm}`
.. admonition:: Lattice Gas Automaton
[P12]_ [P13]_
|br|
:math:`\hspace{3mm}`
.. admonition:: Averaged transport models
[R2]_ [R3]_
|br|
:math:`\hspace{3mm}`
.. admonition:: HDR Thesis
[H1]_
|br|
A developer's guide of LBM_Saclay can be found in ref [R10]_
International journals
----------------------
**Lattice Boltzmann Methods**
.. [P1] Genty A. and V. Pot. Numerical simulation of 3D liquid-gas distribution in porous media by a two-phase lattice Boltzmann method. Transport in Porous Media, 96: 271-294, **2013**. https://doi.org/10.1007/s11242-012-0087-9
.. [P2] Genty A. and V. Pot. Numerical Calculation of Effective Diffusion in Unsaturated Porous Media by the TRT Lattice Boltzmann Method. Transport in Porous Media, 105(2): 391-410, **2014**. https://doi.org/10.1007/s11242-014-0374-8
.. [P3] Pot V., S. PETH, O. MONGA, L.E. VOGEL, A. Genty, P. GARNIER, L. VIEUBLE-GONOD, M. OGURRECK, F. BECKMANN and P.C. BAVEYE. Three-dimensional distribution of water and air in soil pores: Comparison of two-phase two relaxation-times lattice-Boltzmann and morphological model outputs with synchrotron X-ray computed tomography data. Advances in Water Resources, 84: 87-102, **2015**. https://doi.org/10.1016/j.advwatres.2015.08.006
.. [P4] Cartalade A., Younsi A., M. Plapp, Lattice Boltzmann simulations of 3D crystal growth: Numerical schemes for a phase-field model with anti-trapping current. Computers & Mathematics with Applications, 71 (9), pp. 1784–1798, **2016**. https://doi.org/10.1016/j.camwa.2016.02.029
.. [P5] Younsi A. and A. Cartalade, On anisotropy function in crystal growth simulations using Lattice Boltzmann equation. Journal of Computational Physics, 325, pp. 1–21, **2016**. http://dx.doi.org/10.1016/j.jcp.2016.08.014
.. [P6] Genty A., S. GUEDDANI and M. DYMITROWSKA. Computation of Saturation Dependence of Effective Diffusion Coefficient in Unsaturated Argillite Micro-fracture by Lattice Boltzmann Method. Transport in Porous Media, 117(1): 149-168, **2017**. https://doi.org/10.1007/s11242-017-0826-z
.. [P7] BEN HADJ HASSINE S., M. DYMITROWSKA, V. Pot and A. Genty. Gas Migration in Highly Water-Saturated Opalinus Clay Microfractures Using a Two-Phase TRT LBM. Transport in Porous Media, 116(3): 975-1003, **2017**. https://doi.org/10.1007/s11242-016-0809-5
.. [P8] Cartalade A., A. Younsi and M.-C. Néel, Multiple-Relaxation-Time Lattice Boltzmann scheme for fractional advection-diffusion equation. Computer Physics Communications, 234, pp. 40–54, **2019**. https://doi.org/10.1016/j.cpc.2018.08.005
.. [P9] Verdier W., P. Kestener, A. Cartalade, Performance portability of lattice Boltzmann methods for two-phase flows with phase change, Computer Methods in Applied Mechanics and Engineering, 370, 113266, **2020**. https://doi.org/10.1016/j.cma.2020.113266
.. [P10] Boutin T., Verdier W., A. Cartalade, Grand-Potential-based phase-field model of dissolution/precipitation: lattice Boltzmann simulations of counter term effect on porous medium, Computational Materials Science, 207, 111261, **2022**. https://doi.org/10.1016/j.commatsci.2022.111261
.. [P11] Verdier W., A. Cartalade, M. Plapp, Grand-Potential phase field simulations of droplet growth and sedimentation in a two-phase ternary fluid, Modelling and Simulation in Materials Science and Engineering, 32, 065028, **2024**. https://doi.org/10.1088/1361-651X/ad627e
**Lattice Gas Automaton (LGA)**
.. [P12] Pot V. and A. Genty. Dispersion dependence on retardation in a real fracture geometry using lattice-gas cellular automaton. Advances in Water Resources, 30: 273-283, **2007**. https://doi.org/10.1016/j.advwatres.2005.08.011
.. [P13] Pot V. and A. Genty. Sorbing and non-sorbing solute migration in rough fractures with a multi-species LGA model: Dispersion dependence on retardation and roughness. Transport in Porous Media, 59(2): 175-196, **2005**. https://doi.org/10.1007/s11242-004-1175-2
Peer-reviewed proceeding
------------------------
.. [p1] Younsi A., A. Cartalade, M. Quintard, Lattice Boltzmann Simulations for Anisotropic Crystal Growth of a Binary Mixture. Proceeding of The 15th International Heat Transfer Conference (IHTC-15), 9 pages, 10-15 Aug. Kyoto, paper 9797, ISBN: 978-1-56700-421-2. **2014**. http://dx.doi.org/10.1615/IHTC15.cpm.009797
List of PhD thesis and HDR
--------------------------
.. [T1] Younsi A., Simulations des effets des écoulements sur la croissance cristalline d'un mélange binaire. Approche par méthode de Boltzmann sur réseau. Thèse de doctorat CEA/Institut Polytechnique de Paris. **2015**.
.. [H1] Cartalade A., Modèles à champ de phase et équations fractionnaires simulés par méthode de Boltzmann sur réseaux. Mémoire d’Habilitation à Diriger des Recherches (HDR) en Physique, Université Paris-Sud. 95 pages. **2019**. http://dx.doi.org/10.13140/RG.2.2.10705.07529
.. [T2] Verdier W., Phase-field modelling and simulations of phase separation in the two-phase nuclear glass Na :math:`_2` O–SiO :math:`_2` –MoO :math:`_3`. Thèse de doctorat CEA/Institut Polytechnique de Paris. **2022**.
.. [T3] Boutin T., Simulation à l’échelle mésoscopique des gels d’altération des verres nucléaires. Thèse de doctorat CEA/Université Paris-Saclay (ED SMEMaG). https://theses.hal.science/tel-05147983v1. **2025**.
.. [T4] Méjanès C., Modélisation et simulation de la séparation de phase dans les verres nucléaires sous influence de la variation de densité. Thèse de doctorat CEA/Université Paris-Saclay (ED SMEMaG). **2025**.
List of CEA Technical Reports
-----------------------------
.. [R1] Cartalade A., Lattice Boltzmann Method for modelling flow and transport in porous media: natural convection and Darcy-Brinkman-Forchheimer equation. PDF Report DEN-DM2S-SFME-LSET-RT/09-004/A. 52 pages (2 tech notes). **2009**.
.. [R2] Cartalade A., Dual-porosity transport model simulated by a Multiple-Relaxation-Time Lattice Boltzmann Method and application on BEETI experimental device. PDF Report DEN-DM2S-STMF-LATF-RT/11-002/A. 36 pages. **2011**.
.. [R3] Cartalade A. and A. Genty, Effective diffusion of 3D porous media: Lattice Boltzmann simulations.Ref: DEN-DM2S-STMF-LATF-RT/12-016/A. 22 pages. **2012**.
.. [R4] Cartalade A. and É. Régnier, Lattice Boltzmann simulations for crystal growth problems with a phase-field model I: pure substance. Ref: DEN-DM2S-STMF-LATF-RT/12-005/A. 28 pages. **2012**.
.. [R5] Cartalade A., Lattice Boltzmann simulations for crystal growth problems with a phase-field model II: Model with thin interface limit of 3D pure substance. PDF Report DEN-DM2S-STMF-LATF-NT/13-008/A. 30 pages. **2013**.
.. [R6] Younsi A. et A. Cartalade, Comparisons of Lattice Boltzmann schemes for simulating a transport equation with variable parameters and applications on crystal growth problems. Ref: DEN-DM2S-STMF-LATF-NT/14-033/A. 22 pages. **2014**.
.. [R7] Hellaudais V., Younsi A. et A. Cartalade, Simulations of 2D/3D anisotropic shapes of crystal growth by a phase-field model: spherical and cubic harmonics of interfacial energy. Ref: DEN-DM2S-STMF-LMSF-NT/15-003/A. 28 pages. **2015**.
.. [R8] Cartalade A., Comparative simulations of averaged model for simulating flow in porous media.Ref: DEN-DM2S-STMF-LMSF-RT/16-012/A. 19 pages. **2016**.
.. [R9] Verdier W., Modèle à champ de phase pour les systèmes ternaires diphasiques, Rapport DES/ISAS/DM2S/STMF/LMSF/NT/2021-67858/A. 31 pages. **2021**.
.. [R10] Verdier W., Boutin T., P. Kestener, A. Cartalade, LBM_saclay : code HPC multi-architectures sur base LBM. Guide du développeur.PDF Report DES/ISAS/DM2S/STMF/LMSF/NT/2022-70869/A. 116 pages. **2022**.
.. [R11] Boutin T., Modèle champ de phase de dissolution d’un solide à 2 composants : application à l’alteration des verres de stockages borosilicatés. Rapport DES/ISAS/DM2S/STMF/LMSF/NT/2022-70883/A. 31 pages. **2022**.
.. [R12] Méjanès C., Modèle champ de phase de la séparation de phase d’un mélange ternaire dans un verre borro-sillicaté. Rapport DES/ISAS/DM2S/STMF/LMSF/NT/2022-70883/A. 39 pages. **2023**.
Lectures and courses
--------------------
.. [L1] Cartalade A., Cours INSTN CFD diphasique du STMF – Partie 1.C. "Approche thermodynamique des interfaces : les modèles à champ de phase". 325 slides + 50 annexes. **2025**
.. [L2] Cartalade A., Lattice Boltzmann Methods – Part I.A: introduction. "Theory and examples on two-phase flows and phase change". 243 slides. **2025**.