Zobrazeno 1 - 10
of 78
pro vyhledávání: '"D. Nicolas Espinoza"'
Autor:
Matthew L. McLean, D. Nicolas Espinoza
Publikováno v:
Renewable Energy. 202:736-755
Publikováno v:
SPE Journal. 28:289-300
Summary Polymer flooding is an enhanced oil recovery (EOR) method which improves the mobility ratio and sweep efficiency of a waterflood. In theory, the high viscosity of the polymer reduces its injectivity compared to water. However, field studies h
Publikováno v:
Energy & Fuels. 36:9080-9090
Experimental Study of the Effects of Non-Newtonian Polymers on Fracture Opening and Leakoff Patterns
Publikováno v:
Rock Mechanics and Rock Engineering. 55:7021-7034
Autor:
Samantha Fuchs, Dustin Crandall, Johnathan E. Moore, Mayandi Sivaguru, Bruce W. Fouke, D. Nicolas Espinoza, Ange-Therese Akono, Charles J. Werth
Externí odkaz:
https://explore.openaire.eu/search/publication?articleId=doi_________::a46c5e7bc130e5ac01ae8555585a2d63
https://doi.org/10.2139/ssrn.4432933
https://doi.org/10.2139/ssrn.4432933
Publikováno v:
Computational Geosciences. 25:1887-1898
This study presents a workflow to optimize the location of CO2 injectors in order to maximize stored volume and prevent fault reactivation due to increases of pore pressure. We combine coupled reservoir flow and geomechanics simulations with neural n
Publikováno v:
Transport in Porous Media. 139:419-445
Geometric straining of particles in porous media is of critical importance in a broad range of natural and industrial settings, such as contaminant transport in aquifers and the permeability decline due to pore plugging in oil reservoirs. Pore networ
Autor:
Xiaojin Zheng, D. Nicolas Espinoza
Publikováno v:
Rock Mechanics and Rock Engineering. 54:5745-5760
The injection of fluids into a compartmentalized formation induces pore pressure buildup and may result in reactivation of sealing faults. Among other variables, the pore volume compressibility (PVC) can affect the amount of pore pressure change duri
Publikováno v:
Day 1 Mon, October 03, 2022.
Geological storage of carbon dioxide (CO2) in depleted gas reservoirs represents a cost-effective solution to mitigate global carbon emissions. The surface chemistry of the reservoir rock, pressure, temperature, and moisture content are critical fact