Y
Youngseuk Keehm
Researcher at Kongju National University
Publications - 36
Citations - 1607
Youngseuk Keehm is an academic researcher from Kongju National University. The author has contributed to research in topics: Permeability (earth sciences) & Wave propagation. The author has an hindex of 12, co-authored 36 publications receiving 1341 citations. Previous affiliations of Youngseuk Keehm include Stanford University & Seoul National University.
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Digital rock physics benchmarks-Part I: Imaging and segmentation
Heiko Andrä,Nicolas Combaret,Jack Dvorkin,Erik Glatt,Junehee Han,Matthias Kabel,Youngseuk Keehm,Fabian Krzikalla,Minhui Lee,Claudio Madonna,Mike Marsh,Tapan Mukerji,Erik H. Saenger,Ratnanabha Sain,Nishank Saxena,Sarah Ricker,Andreas Wiegmann,Xin Zhan +17 more
TL;DR: The goal is to explore and record the variability of the computed effective properties as a function of using different tools and workflows, and benchmarking is the topic of the two present companion papers.
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Digital rock physics benchmarks-part II: Computing effective properties
Heiko Andrä,Nicolas Combaret,Jack Dvorkin,Erik Glatt,Junehee Han,Matthias Kabel,Youngseuk Keehm,Fabian Krzikalla,Minhui Lee,Claudio Madonna,Mike Marsh,Tapan Mukerji,Erik H. Saenger,Ratnanabha Sain,Nishank Saxena,Sarah Ricker,Andreas Wiegmann,Xin Zhan +17 more
TL;DR: This analysis provides the DRP community with a range of possible outcomes which can be expected depending on the solver and its setup, and falls within the ranges consistent with the relevant laboratory data.
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Permeability prediction from thin sections: 3D reconstruction and Lattice‐Boltzmann flow simulation
TL;DR: In this paper, the Lattice-Boltzmann (LB) technique is used to reconstruct 3D porous media from 2D thin sections and 3D flow simulation is performed on the reconstructed porous media.
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Digital rock physics: Effect of fluid viscosity on effective elastic properties
TL;DR: In this paper, the effect of pore fluid viscosity on effective elastic properties using digitized rocks is investigated using a virtual rock physics approach and a displacement-stress rotated staggered finite-difference grid technique.
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Computational rock physics at the pore scale: Transport properties and diagenesis in realistic pore geometries
TL;DR: The Lattice Boltzmann method (LBM) as discussed by the authors describes fluid motion as collisions of imaginary particles, which are much bigger than the real fluid molecules These particles have nearly nothing in common with real fluids, but they show almost the same behavior at a macroscopic scale.