skip to main content
OSTI.GOV title logo U.S. Department of Energy
Office of Scientific and Technical Information

Title: Two-phase flow in porous media: Crossover from capillary fingering to compact invasion for drainage

Journal Article · · Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics
; ;

It had been predicted that the capillary fingering observed at small capillary numbers should change or cross over to compact invasion at larger capillary numbers or longer times [D. Wilkinson, Phys. Rev. A 34, 1380 (1986)]. We present results from pore-level modeling in two dimensions for the average position (related to the position of the interface) of the injected fluid as well as the width of the interface between the injected, nonwetting fluid and the defending, wetting fluid. These results are entirely consistent with the predicted crossover from the fractal flow characterized by invasion percolation with trapping (IPWT) to compact/linear/stable flow, where the position of the injected fluid advances linearly with time and where the width of the interface is constant. Furthermore, our results for the characteristic time, at which the crossover occurs, agree with the predictions of Wilkinson. To focus on the effect of capillary number, we are considering only viscosity-matched flows where both fluids have the same viscosities. To our knowledge, these are the first pore-level modeling results that quantitatively test the general predictions of Wilkinson for this capillary crossover in the case of drainage. Our modeling results are used to provide closed form expressions predicting the dependence of average position and interfacial width upon capillary number and time, regardless of the size of the system. The size scaling inherent in the crossover combined with our results locating the upper and lower bounds of the crossover regime enable us to predict the location of the crossover for two-dimensional systems of different size. These predictions are compared with flow patterns from experiments in the literature. The agreement between our predictions and the experimental flow patterns indicates that the experiments exhibit the same IPWT to compact crossover observed in our modeling.

Research Organization:
National Energy Technology Laboratory (NETL), Pittsburgh, PA, Morgantown, WV, and Albany, OR (United States)
Sponsoring Organization:
USDOE - Office of Fossil Energy (FE)
DOE Contract Number:
None cited
OSTI ID:
924737
Report Number(s):
DOE/NETL-IR-2005-088; TRN: US200809%%332
Journal Information:
Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics, Vol. 71, Issue 2, pt. 2; ISSN 1539-3755
Publisher:
American Physical Society, College Park, MD
Country of Publication:
United States
Language:
English

References (32)

Fractal nature of viscous fingering in two-dimensional pore level models journal April 1995
Morphology and dynamics of interfaces in random two-dimensional media journal September 1993
Pore-level modeling of drainage: Crossover from invasion percolation fingering to compact flow journal May 2003
Immiscible displacement of viscosity-matched fluids in two-dimensional porous media journal March 1997
Capillary displacement and percolation in porous media journal June 1982
Dynamics of stable viscous displacement in porous media journal March 2000
Dynamics of growing interfaces from the simulation of unstable flow in random media journal May 1994
Macroscopic parameters from simulations of pore scale flow journal October 1990
Flow in porous media — pore-network models and multiphase flow journal June 2001
Invasion percolation: a new form of percolation theory journal October 1983
Percolation model of immiscible displacement in the presence of buoyancy forces journal July 1984
Fractal nature of viscous fingering in three-dimensional pore-level models journal March 1996
Crossover from fractal to compact growth from simulations of two-phase flow with finite viscosity ratio in two-dimensional porous media journal May 1992
Dispersion in Disordered Porous Media journal November 1983
Invasion percolation: new algorithms and universality classes journal November 1999
Correlation of the two-phase flow coefficients of porous media with the rheology of shear-thinning fluids journal January 2004
Numerical pore-scale modeling of three-phase fluid flow: Comparison between simulation and experiment journal April 1999
Critical phenomena in fluid invasion of porous media journal February 1991
Fractal structure of diffusion and invasion fronts in three-dimensional lattices through the gradient percolation approach journal February 1988
Viscous and capillary pressures during drainage: Network simulations and experiments journal November 1997
Pore-Scale Viscous Fingering in Porous Media journal October 1985
Fractal Growth Phenomena journal January 1989
Simulating temporal evolution of pressure in two-phase flow in porous media journal August 1998
Nonequilibrium capillary pressure and relative permeability curves of porous media journal October 2003
Numerical models and experiments on immiscible displacements in porous media journal April 1988
Fractal dimension and avalanches of invasion percolation: the effect of aspect ratio journal March 2004
Crossover from fractal to compact flow from simulations of two-phase flow with finite viscosity ratio in two-dimensional porous media journal April 1993
Pore-level modeling of immiscible drainage: validation in the invasion percolation and DLA limits journal March 2003
The effect of morphological disorder on hydrodynamic dispersion in flow through porous media journal October 1988
Spatial distribution of avalanches in invasion percolation: their role in fingering journal August 2002
Percolation effects in immiscible displacement journal August 1986
Modified drag theory of permeability journal January 1985

Similar Records

Crossover from capillary fingering to compact invasion for two-phase drainage with stable viscosity ratios
Journal Article · Thu Feb 01 00:00:00 EST 2007 · Advances in Water Resources · OSTI ID:924737
Crossover from fractal capillary fingering to compact flow: The effect of stable viscosity ratios
Journal Article · Mon Oct 01 00:00:00 EDT 2007 · Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics · OSTI ID:924737
Crossover from fractal capillary fingering to compact flow: The effect of stable viscosity ratios
Journal Article · Mon Oct 01 00:00:00 EDT 2007 · Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics (Print) · OSTI ID:924737

Related Subjects

42 ENGINEERING
TWO-PHASE FLOW
DRAINAGE
CAPILLARY FLOW
VISCOSITY
FLOW MODELS
POROUS MATERIALS
TWO-DIMENSIONAL CALCULATIONS