%0 Journal Article %1 Berg05032013 %A Berg, Steffen %A Ott, Holger %A Klapp, Stephan A. %A Schwing, Alex %A Neiteler, Rob %A Brussee, Niels %A Makurat, Axel %A Leu, Leon %A Enzmann, Frieder %A Schwarz, Jens-Oliver %A Kersten, Michael %A Irvine, Sarah %A Stampanoni, Marco %D 2013 %J Proceedings of the National Academy of Sciences %K foams in-situ morphology tomography x-rays %N 10 %P 3755-3759 %R 10.1073/pnas.1221373110 %T Real-time 3D imaging of Haines jumps in porous media flow %U http://www.pnas.org/content/110/10/3755.abstract %V 110 %X Newly developed high-speed, synchrotron-based X-ray computed microtomography enabled us to directly image pore-scale displacement events in porous rock in real time. Common approaches to modeling macroscopic fluid behavior are phenomenological, have many shortcomings, and lack consistent links to elementary pore-scale displacement processes, such as Haines jumps and snap-off. Unlike the common singular pore jump paradigm based on observations of restricted artificial capillaries, we found that Haines jumps typically cascade through 10–20 geometrically defined pores per event, accounting for 64% of the energy dissipation. Real-time imaging provided a more detailed fundamental understanding of the elementary processes in porous media, such as hysteresis, snap-off, and nonwetting phase entrapment, and it opens the way for a rigorous process for upscaling based on thermodynamic models.

@article{Berg05032013, abstract = {Newly developed high-speed, synchrotron-based X-ray computed microtomography enabled us to directly image pore-scale displacement events in porous rock in real time. Common approaches to modeling macroscopic fluid behavior are phenomenological, have many shortcomings, and lack consistent links to elementary pore-scale displacement processes, such as Haines jumps and snap-off. Unlike the common singular pore jump paradigm based on observations of restricted artificial capillaries, we found that Haines jumps typically cascade through 10–20 geometrically defined pores per event, accounting for 64% of the energy dissipation. Real-time imaging provided a more detailed fundamental understanding of the elementary processes in porous media, such as hysteresis, snap-off, and nonwetting phase entrapment, and it opens the way for a rigorous process for upscaling based on thermodynamic models.}, added-at = {2013-05-20T12:07:33.000+0200}, author = {Berg, Steffen and Ott, Holger and Klapp, Stephan A. and Schwing, Alex and Neiteler, Rob and Brussee, Niels and Makurat, Axel and Leu, Leon and Enzmann, Frieder and Schwarz, Jens-Oliver and Kersten, Michael and Irvine, Sarah and Stampanoni, Marco}, biburl = {https://www.bibsonomy.org/bibtex/24a95ce11181472a9a525ef043517d601/alex_ruff}, description = {Real-time 3D imaging of Haines jumps in porous media flow}, doi = {10.1073/pnas.1221373110}, eprint = {http://www.pnas.org/content/110/10/3755.full.pdf+html}, interhash = {a96b142f0e63270d0aaaccfedb094281}, intrahash = {4a95ce11181472a9a525ef043517d601}, journal = {Proceedings of the National Academy of Sciences}, keywords = {foams in-situ morphology tomography x-rays}, number = 10, pages = {3755-3759}, timestamp = {2013-05-20T12:07:33.000+0200}, title = {Real-time 3D imaging of Haines jumps in porous media flow}, url = {http://www.pnas.org/content/110/10/3755.abstract}, volume = 110, year = 2013 }