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Title: Leakoff assessment of nanoparticle-stabilized CO2 foams for fracturing applications

Journal Article · · Journal of Natural Gas Science and Engineering
ORCiD logo [1];  [2];  [2]
  1. Univ. of Louisiana, Lafayette, LA (United States); OSTI
  2. Univ. of Louisiana, Lafayette, LA (United States)
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The leakoff of multiphase systems through porous media is a complicated process. In this study, we have designed an experimental setup that is used to assess the leakoff of the liquid and gas phase under pressurized conditions. The novelty of this study is that while most previous studies utilized fluid/gas in the aqueous phase, nanoparticles are introduced in this study, which formed a solid/fluid/gas multiphase system to boost foam performance and reduce leakoff. In the parametric experimental analysis, the effects of foam quality, core permeability, surfactant concentration, and polymer concentration on the dynamic and static leakoff rates of liquid and gas are evaluated. It was found that core permeability affects the leakoff of foam the most with a leakoff coefficient of up to 1.37015 $$ft/\sqrt{min}$$ for gas and up to 0.1056 $$ft/\sqrt{min}$$ for liquid under the experiment settings herein. The leakoff rate of gas is generally several magnitudes higher than that of the liquid. When CO2 gas is present in the foam, the leakoff coefficient falls in the range between 0 and 1.37015 $$ft/\sqrt{min}$$ for gas, and between 0.0005 and 0.1056 $$ft/\sqrt{min}$$ for liquid. Finally, the methodology and results of this study shed light on the mechanistic understanding of the leakoff properties of multiphase systems and could be used to assist the design of foam fracturing for reservoir stimulation.

Research Organization:
Univ. of Louisiana, Lafayette, LA (United States)
Sponsoring Organization:
USDOE Office of Fossil Energy (FE)
Grant/Contract Number:
FE0031575
OSTI ID:
1977363
Journal Information:
Journal of Natural Gas Science and Engineering, Journal Name: Journal of Natural Gas Science and Engineering Journal Issue: C Vol. 100; ISSN 1875-5100
Publisher:
ElsevierCopyright Statement
Country of Publication:
United States
Language:
English

References (16)

Effect of polymer foam morphology and density on kinetics ofin vitro controlled release of isoniazid from compressed foam matrices journal April 1997
Improving hydraulic fracturing effectiveness in depleted and low-pressure reservoirs using N2-energized fluids journal January 2021
Experimental study of nanoparticle-surfactant-stabilized CO2 foam: Stability and mobility control journal July 2016
Experimental study on the dynamic filtration control performance of N 2 /liquid CO 2 foam in porous media journal August 2017
Investigation of gas flow hindrance due to fracturing fluid leakoff in low permeability sandstones journal March 2014
Experimental investigation of shale gas production impairment due to fracturing fluid migration during shut-in time journal May 2015
A review of shale swelling by water adsorption journal November 2015
Practical considerations for diagnostic fracture injection test (DFIT) analysis journal December 2018
Rheology and stability of nanoparticle-stabilized CO2 foam under reservoir conditions journal January 2021
Controlling Shale Swelling and Fluid Loss Properties of Water-Based Drilling Mud via Ultrasonic Impregnated SWCNTs/PVP Nanocomposites journal July 2020
Study of Nanoparticle–Surfactant-Stabilized Foam as a Fracturing Fluid journal September 2015
Investigation of the Effect of Nanoparticle-Stabilized Foam on EOR: Nitrogen Foam and Methane Foam journal July 2020
Foaming and Foam Stability for Mixed Polymer–Surfactant Solutions: Effects of Surfactant Type and Polymer Charge journal March 2012
Dynamic Fluid Loss Characteristics of Foam Fracturing Fluids journal October 1985
Control and Modeling of Fluid Leakoff During Hydraulic Fracturing journal June 1985
Dynamic Fluid-Loss Characteristics of CO2-Foam Fracturing Fluids journal May 1987

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03 NATURAL GAS
CO2 foam
Energy & Fuels
Engineering
Foam fracturing
Foam leakoff
Nanoparticle