±¨ ¸æ ÈË£ºËïÊ÷褠ɳÌØ°¢²·¶ÅÀ­¹úÍõ¿Æ¼¼´óѧ½ÌÊÚ

±¨¸æʱ¼ä£º11 Ô 4ÈÕ 16:00

±¨¸æµØµã£ºÃ÷־¥A536

±¨¸æÈ˼ò½é£ºËïÊ÷褣¬É³ÌØ°¢²·¶ÅÀ­¹úÍõ¿Æ¼¼´óѧ½ÌÊÚ£¬2020Äê¶ÈÈëÑ¡Öйú½ÌÓý²¿³¤½­Ñ§Õß½²×ù½ÌÊÚ¡£ËûÏȺóÓÚ1991ÄêºÍ1994Äê±ÏÒµÓÚÌì½ò´óѧ»ñ¹¤Ñ§Ñ§Ê¿ºÍ¹¤Ñ§Ë¶Ê¿Ñ§Î»£¬Ëæºó¼ÌÐø¾Í¶ÁÓÚÌì½ò´óѧºÍÃÀ¹úµÂ¿ËÈø˹´óѧ°Â˹¶¡·ÖУ²¢±ÏÒµ»ñ»¯Ñ§¹¤³Ìרҵ (1997Ä꣬ʦ´ÓÖйú¿ÆѧԺԺʿÓà¹úçý) ºÍ¼ÆËãÓëÓ¦ÓÃÊýѧרҵ (2003Ä꣬ʦ´ÓÃÀ¹ú¹ú¼Ò¹¤³ÌԺԺʿMary Wheeler) Ë«²©Ê¿Ñ§Î»¡£ ËûÓÚ2003ÄêÖÁ2009Äê¼äÏȺóÔÚÃÀ¹úµÂ¿ËÈø˹´óѧ°Â˹¶¡·ÖУÈβ©Ê¿ºóºÍ¸±Ñо¿Ô±¼°ÔÚÃÀ¹ú¿ËÀ³Ä·É­´óѧÈÎÖúÀí½ÌÊڼ沩ʿÉúµ¼Ê¦¡£2009Äê8Ô£¬Ëû×÷Ϊ°Ùλ´´Ð£½ÌÊÚÖ®Ò»¼ÓÃË°¢²·¶ÅÀ­¹úÍõ¿Æ¼¼´óѧ (KAUST£¬US NewsÅÅÃûÈ«ÇòÇ°Ò»°Ù) ÖÁ½ñ£¬Ä¿Ç°ÈθÃУ¼ÆËã´«ÖÊÏÖÏóʵÑéÊÒ(CTPL)Ö÷ÈΣ¬µØÇò¿Æѧϵ½ÌÊÚ£¬Ê¯Ó͹¤³Ìϵ½ÌÊÚºÍÊýѧϵ½ÌÊÚ¡£ÒÑ·¢±íSCIÆÚ¿¯ÂÛÎÄ390Óàƪ£¬×ܼƱ»Òý³¬¹ý12200Óà´Î£¬HÖ¸Êý56¡£ÏȺóÖ¸µ¼Ë¶²©Ñо¿Éú¹²50ÓàÃû(ÒѱÏÒµ²©Ê¿15Ãû)£¬²©Ê¿ºóÑо¿ÈËÔ±20Óàλ¡£Ä¿Ç°¼æÈÎ Journal of Computational Physics (JCP)£¬Gas Science and Engineering£¬InterPore Journal ºÍ Computational Geoscience µÈ¹ú¼ÊÖªÃûÆÚ¿¯µÄ¸±Ö÷±à£¬ÒÔ¼° Applied Energy£¬Applied Thermal Engineering£¬Fuel£¬Computer Methods in Applied Mechanics and Engineering µÈ¹ú¼ÊÖªÃûÆÚ¿¯¿Í×ùÖ÷±à¡£Ëû´Ó2020ÄêÆðÖÁ½ñ£¬Á¬ÐøÎåÄêÈëÑ¡ÁË¡°¹¤³Ìѧ¿ÆÈ«Çò¶¥¼â¿Æѧ¼Ò¡± (˹̹¸£´óѧ·¢²¼µÄÈ«ÇòÇ°2%¶¥¼â¿Æѧ¼Ò°ñµ¥)£»²¢ÔÚ¹¤³ÌºÍÊýѧÁ½¸öѧ¿Æ¶¼ÈÙÁйú¼ÊÖªÃûѧÊõÍøÕ¾ Research.com ·¢²¼µÄ 2024 Äê¶ÈÈ«Çò¶¥¼â¿Æѧ¼ÒÃû¼£¬ÅÅÃûÈ«ÇòµÚ1922Ãû¡£ËûÄ¿Ç°ÊÇInterPore Saudi ChapterµÄÖ÷ϯ¡£

±¨¸æÄÚÈÝÕªÒª£ºDarcy-scale multi-phase flow simulation in subsurface reservoirs has routinely used by reservoir engineers over half a century. More recently, digital Rock Physics (DRP) and pore-scale flow simulation have also become a complementary part in reservoir characterization over the past two or three decades as non-destructive methods used to determine absolute/relative permeability, capillarity, effective elastic rock parameters and other porous media properties. In the recent two decades, the Navier¨CStokes¨CCahn¨CHilliard (NSCH) system has started to merge as the standard model for the Direct Numerical Simulation (DNS) of incompressible immiscible two-phase flow, with finite volume methods (FVM), finite element methods (FEM), Lattice Boltzmann methods (LBM), and Smoothed Particles Hydrodynamics (SPH) as popular discretization schemes. Since DNS is computationally expensive with complex geometrical pore space, a simplified yet powerful strategy known as the pore network model (PNM) has been constructed and applied widely for simulating a variety of different physical and chemical processes in porous media, including capillarity effect, phase exchange, non-Newtonian displacement, non-Darcy flow, and reactive transport; but slippage effects, adsorption, desorption, and confinement effects within tight pore channels still require models in smaller scales such as molecular dynamics (MD) simulations.

In this talk, we share a few of our recent works in digital rock physics and pore-scale flow simulation, including 1) our research on the two-scale molecular dynamics¨CMonte Carlo (MD-MC) framework with applications in tight pore-scale phenomena including transport of shale gas/oil and leakage of subsurface hydrogen storage; 2) our ongoing research on energy-stable strategy of Lattice Boltzmann method (LBM) with applications on two-phase flow and reactive transport in porous media; 3) our novel SPH-based particle method for pore-scale flow simulation, which preserves not only mass, momentum but also energy dissipation law in the discrete solution; and 4) the pore network model (PNM) described from model reduction viewpoint for pore-scale fluid flow as well as our new pixel-free algorithm of pore-network model extraction known as the flashlight search medial axis algorithm. Numerical examples are provided to demonstrate the advantages of the new models and/or algorithms.

Ö÷°ìµ¥Î»£ºÍÁľ¹¤³ÌÓë²â»æѧԺ

¿Æѧ¼¼Êõ·¢Õ¹Ñо¿Ôº