Acid Fracturing Carbonate-Rich Shale: A Feasibility Investigation of Eagle Ford Formation

Cash, Rachael; Zhu, Ding; Hill, A.D.

doi:10.2118/181805-ms

Cited by 15 publications

(6 citation statements)

References 9 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…act as proppant to prop the fractures under closure pressure. The experiment of acidizing in shale by Cash et al 15 showed that acidizing with 28% HCL produces a high initial conductivity, which reduces sharply in the latter period, and treatment with 15% HCL produces a constantly high conductivity. It is thought that a higher content of carbonatite in shale results in a larger dissolution space, and high conductivity is likely to generate.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Acid Fracturing Treatments in Shale Formation

et al. 2017

View full text Add to dashboard Cite

Hydraulic fracturing by stimulated reservoir volume (SRV) is a necessity to realize commercial development of shale gas, and its stimulation mechanism still needs further study, and the effectiveness of supplementary stimulation measures needs further exploration. The shale always contains some carbonate minerals. This paper tests the permeability of acid-etched fracture in shale to explore the influence of carbonate mineral content, acid fluid types and concentration, fracture plane roughness, proppant, and confining pressure on the acid-etched effects in shale, and uses CT scanning to conduct research on variation of microscopic pore-throat texture in shale before and after acid-etching. The test shows that the roughness of the fracture plane perpendicular to the bedding plane is higher than the roughness of that paralleled to the bedding plane, and the roughness in both fracture planes perpendicular to and paralleled to the bedding plane increases as the carbonate minerals content increases. In same group of shale samples, the permeability of self-propped fracture before and after acid-etching respectively is positively correlated with the fractal dimension of the fracture plane before and after acid-etching, and the variation of permeability of self-propped fracture before and after acid-etching is also positively correlated with the variation of fractal dimension of fracture plane before and after acid-etching, which is not shown in different groups of shale samples. When the content of carbonate minerals in shale is between 10% and 30%, the relation between optimum HCL concentration and carbonate mineral content is expressed as Y (OptimumHCLconcentration) = −0.5X (Carbonatemineralcontent) + 0.15. If the shale has a high carbonate mineral content (>30%), the effect of acid-etching is not easily controlled, so the technique of acid fracturing should be carried out cautiously. The permeability of single-layer proppant and self-propped fracture after acid-etching conforms to Walsh theory within certain pressure, and variation and migration of curve slope reflects unstable arrangement, imbedding, and crush of proppant, and nonreactive filled impurity of clay and quartz desquamated and migrated, which coincides well with constant variation of permeability. Applying proper acid fluids and optimum concentration in shale with varying carbonate contents will increase pore size, fracture width, and fracture number. For the shale with abundant calcite-cemented fractures, the optimum acid fluid concentration should be increased properly. Due to ultralow permeability of the matrix in shale, even high concentration acid fluid could not penetrate the core with barren natural fractures or calcium-filled fractures. The results of research provide valuable information for design of acid fracturing in shale play.

show abstract

Section: Introductionmentioning

confidence: 99%

Evaluation of Acid Fracturing Treatments in Shale Formation

et al. 2017

View full text Add to dashboard Cite

show abstract

“…Acid fracturing for stimulating carbonate-rich shale, such as calcareous mudstone, has been examined as a method for improving conductivity and matrix permeability by etching the microfractures. , Experimental studies on different shale samples concluded that dilute acid concentrations that are optimized for specific materials are necessary to balance hydrocarbon recovery and unfavorable rock weakening by dissolving carbonate minerals from the rock matrix. − These studies have provided an understanding of changing permeability, porosity, and constitutive properties that are utilized in continuum-scale models for simulating macroscopic fracture dynamics. , …”

Section: Chemical Reactions Of Hff With Minerals and Organic Matter I...mentioning

confidence: 88%

Chemical and Reactive Transport Processes Associated with Hydraulic Fracturing of Unconventional Oil/Gas Shales

et al. 2022

View full text Add to dashboard Cite

Hydraulic fracturing of unconventional oil/gas shales has changed the energy landscape of the U.S. Recovery of hydrocarbons from tight, hydraulically fractured shales is a highly inefficient process, with estimated recoveries of <25% for natural gas and <5% for oil. This review focuses on the complex chemical interactions of additives in hydraulic fracturing fluid (HFF) with minerals and organic matter in oil/gas shales. These interactions are intended to increase hydrocarbon recovery by increasing porosities and permeabilities of tight shales. However, fluid–shale interactions result in the dissolution of shale minerals and the release and transport of chemical components. They also result in mineral precipitation in the shale matrix, which can reduce permeability, porosity, and hydrocarbon recovery. Competition between mineral dissolution and mineral precipitation processes influences the amounts of oil and gas recovered. We review the temporal/spatial origins and distribution of unconventional oil/gas shales from mudstones and shales, followed by discussion of their global and U.S. distributions and compositional differences from different U.S. sedimentary basins. We discuss the major types of chemical additives in HFF with their intended purposes, including drilling muds. Fracture distribution, porosity, permeability, and the identity and molecular-level speciation of minerals and organic matter in oil/gas shales throughout the hydraulic fracturing process are discussed. Also discussed are analysis methods used in characterizing oil/gas shales before and after hydraulic fracturing, including permeametry and porosimetry measurements, X-ray diffraction/Rietveld refinement, X-ray computed tomography, scanning/transmission electron microscopy, and laboratory- and synchrotron-based imaging/spectroscopic methods. Reactive transport and spatial scaling are discussed in some detail in order to relate fundamental molecular-scale processes to fluid transport. Our review concludes with a discussion of potential environmental impacts of hydraulic fracturing and important knowledge gaps that must be bridged to achieve improved mechanistic understanding of fluid transport in oil/gas shales.

show abstract

“…Thus, tracking the effect of changing one condition on the resulting conductivity will be a challenge. An extensive literature review was applied to gather published data on the API acid fracture conductivity experiments. ,,,− It is worth mentioning that the data collected are consistent as they are obtained from the same laboratory using the same experimental procedure. Table illustrates the physical properties, meanings, and units of different features.…”

Section: Data Gathering and Handlingmentioning

confidence: 98%

“…A recent study has also shown that acid-fracture fluid type could alter the pattern of rock removal which has a significant effect on the conductivity, even more so than the volume of the dissolved rock . For example, conductivity is higher when the acid fracture treatment creates channels rather than rough surfaces, given that they could withstand closure stress. − The leaking of acid from the fracture into the surrounding rock matrix can also result in more heterogeneous fracture surfaces that enhance conductivity if the rock’s mechanical properties are unharmed …”

Section: Introductionmentioning

confidence: 99%

Data-Driven Acid Fracture Conductivity Correlations Honoring Different Mineralogy and Etching Patterns

et al. 2020

View full text Add to dashboard Cite

Acid-fracturing operations are mainly applied in tight carbonate formations to create a highly conductive path. Estimating the conductivity of a hydraulic fracture is essential for predicting the fractured well productivity. Several models were developed previously to estimate the conductivity of acid-fractured rocks. In this research, machine learning methods were applied to 560 acid fracture experimental datapoints to develop several conductivity correlations that honor the rock types and etching patterns. Developing one universal correlation often results in significant error. To develop conductivity correlations, various data preprocessing methods were applied to remove the outliers and failed experiments. Features that did not contribute to precise predictions were removed through regularization. A machine learning classifier was built to predict the etching pattern based on the input data. We generated a multivariate linear regression model and compared it with other models generated through ridge regression. In addition to that, artificial neural network-based model was proposed to predict the fracture conductivity of several carbonate rocks such as dolomite, chalk, and limestone. The performance of the developed models was assessed using well-known metrics such as precision, accuracy, mean squared error, recall, and correlation coefficients. Cross-validation was also employed to assure accuracy and avoid overfitting. The classifier accuracy was 93%, while the regression model resulted in a relatively high correlation coefficient.

show abstract

Acid Fracturing Carbonate-Rich Shale: A Feasibility Investigation of Eagle Ford Formation

Cited by 15 publications

References 9 publications

Evaluation of Acid Fracturing Treatments in Shale Formation

Evaluation of Acid Fracturing Treatments in Shale Formation

Chemical and Reactive Transport Processes Associated with Hydraulic Fracturing of Unconventional Oil/Gas Shales

Data-Driven Acid Fracture Conductivity Correlations Honoring Different Mineralogy and Etching Patterns

Contact Info

Product

Resources

About