The Next Generation of Regenerative Catalytic Breakers for Use in Alkaline and High-Temperature Fracturing Fluids

Armstrong, Charles D.; Stevens, R. F.; Le, Hoang V.; Stephenson, Christopher; Qu, Qi

doi:10.2118/127936-ms

Cited by 12 publications

(6 citation statements)

References 8 publications

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“…The Oxidant-breakers' ability for breaking the polymer is limited by their stoichiometric reaction (Armstrong et al, 2010) and their incapacity to regenerate their chemical activity. Furthermore, the high temperature induced a rapid decomposition of the breakers into highly reactive free radicals (Kidd, 2001).…”

Section: Polymer Degraded In the Fracturing Fluid Linear Gelmentioning

confidence: 99%

“…Moreover, enzymes have the ability to regenerate their catalytic activity, catalyzing the hydrolysis of the polymer continuously. However, the fact that the enzyme -after four hours of reaction did not continue catalyzing the hydrolysis of the polymerindicates that it was denaturized due to high temperature (Armstrong et al, 2010).…”

Section: Polymer Degraded In the Fracturing Fluid Linear Gelmentioning

confidence: 99%

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Post-fracturing treatments design to redress the damage caused by fracturing fluid polymers

Carrascal-Delgado

Pachón-Contreras

Molina-Velasco

2014

CT&F Cienc. Tecnol. Futuro

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even chemical products with different chemical properties were evaluated as post-fracturing treatments to remove the polymer retained in the pore system of the fracture and adjacent rock after hydraulic fracturing. Three of those chemical products were used for the first time to degrade the polymer in fracturing fluids. All laboratory tests were conducted under the Unit K-1 Chichimene oil-field conditions -located in Eastern Colombia, and operated by Ecopetrol S.A.Fluid-fluid and fluid-rock compatibility tests were performed. In order to evaluate the capacity of the post-fracturing treatments to degrade the polymer in the fracturing fluid, a new methodology for polymer quantification was implemented. The chemical and thermal stability of the post-fracturing treatments was assessed trough coreflooding experiments. Finally, the evaluations of the effectiveness of the post-fracturing treatments were performed and assessed with coreflooding experiments using fractured rocks as porous media.The coreflooding results showed that the post-fracturing treatments evaluated promoted the recovery of about 40% of the total polymer retained in the porous system, and improved the retained permeability in values between 50 and 180%. The best obtained results came from the first-time usage of chemical products as post-fracturing treatments.

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Section: Polymer Degraded In the Fracturing Fluid Linear Gelmentioning

confidence: 99%

Section: Polymer Degraded In the Fracturing Fluid Linear Gelmentioning

confidence: 99%

Post-fracturing treatments design to redress the damage caused by fracturing fluid polymers

Carrascal-Delgado

Pachón-Contreras

Molina-Velasco

2014

CT&F Cienc. Tecnol. Futuro

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“…However, enzymes are very temperature and pH sensitive . Oxidizers, on the other hand, have negative impacts on equipment and the environment, and are used up during the reaction . Some attempts have been made to develop enzymes for high temperature applications.…”

Section: Introductionmentioning

confidence: 99%

“…29 Oxidizers, on the other hand, have negative impacts on equipment and the environment, and are used up during the reaction. 30 Some attempts have been made to develop enzymes for high temperature applications. Zhang et al 29 have reported a thermostable mannanase enzyme that belongs to the glucanase family, which was originally discovered in a hydrothermal vent sample.…”

Section: Introduction Of Encapsulated Breakers Allows High Concentra-mentioning

confidence: 99%

A review of fracturing fluid systems used for hydraulic fracturing of oil and gas wells

Barati

Liang

2014

J of Applied Polymer Sci

618

341

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Hydraulic fracturing has been used by the oil and gas industry as a way to boost hydrocarbon production since 1947. Recent advances in fracturing technologies, such as multistage fracturing in horizontal wells, are responsible for the latest hydrocarbon production boom in the US. Linear or crosslinked guars are the most commonly used fluids in traditional fracturing operations. The main functions of these fluids are to open/propagate the fractures and transport proppants into the fractures. Proppants are usually applied to form a thin layer between fracture faces to prop the fractures open at the end of the fracturing process. Chemical breakers are used to break the polymers at the end of the fracturing process so as to provide highly conductive fractures. Concerns over fracture conductivity damage by viscous fluids in ultra-tight formations found in unconventional reservoirs prompted the industry to develop an alternative fracturing fluid called "slickwater". It consists mainly of water with a very low concentration of linear polymer. The low concentration polymer serves primarily to reduce the friction loss along the flow lines. Proppant-carrying capability of this type of fluids is still a subject of debate among industry experts. Constraints on local water availability and the potential for damage to formations have led the industry to develop other types of fracturing fluids such as viscoelastic surfactants and energized fluids. This article reviews both the traditional viscous fluids used in conventional hydraulic fracturing operations as well as the new family of fluids being developed for both traditional and unconventional reservoirs.

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“…Even before state and federal agencies began to focus on the environmental impacts of shale development, responsible service providers were developing new fluids and technologies to minimize environmental, health, and safety risks of hydraulic fracturing operations. For example, biotechnology research enables the replacement of conventional oxidative breakers with polymer-specific enzyme technology that breaks the viscosity of polymers used in hydraulic fracturing applications (Armstrong et al, 2010). Enzyme breakers improve performance because of their inherent substrate specificity and their potential to degrade polymers infinitely.…”

Section: Introductionmentioning

confidence: 99%

Chlorophyll: A Naturally Occurring Green Polymer Breaker for Hydraulic Fracturing

Dhulipala

Armstrong

2016

SPE International Conference and Exhibition on Formation Damage Control

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Porphyrins produce free radicals in alkaline conditions. Chlorophyll is an Mg ϩϩ -containing tetrapyrrole formed from 4 porphyrin rings and is part of the photosynthetic reactions in plants (Arnoff, 1966). It catalyzes carbohydrate synthesis in the presence of light and carbon dioxide. Using the molecular structure of chlorophyll, we hypothesized that chlorophyll functions as a breaker by producing hydrogen peroxide or other radicals in the alkaline environments of borate-fracturing fluids.This study evaluated leaf extract containing chlorophyll as a potential polymer breaker. Leaves contain 1.5 to 2.5% of chlorophyll in their leaves and the ratio of chlorophyll a to b is 2.5-3.5 depending on growth conditions and light exposure (Willstaetter and Stoll, 1928). Chlorophyll samples were obtained from various plants and commercial sources, and their efficacy as polymer breakers was studied against guar-based fracturing fluids. The average molecular weight of treated fluids was measured by changes in intrinsic viscosity. Additionally, regain conductivity measurements were carried out. Results showed an 84% regain conductivity in proppant packs. Chlorophyll-treated cross-linked fluids showed a more than 90% viscosity reduction, without any viscosity rebound on cooling. The chlorophyll worked efficiently up to 250°F but the optimum temperatures are at 175 to 200°F with narrow pH range of 9.5 to 10. The chlorophyll-treated fluids also showed a reduction of molecular weights of the linear guar polymer from 1,472,000 to 138,000 as measured by the intrinsic viscosity method. The studies support the hypothesis that chlorophyll can function as a polymer breaker for alkaline fracturing fluids.

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The Next Generation of Regenerative Catalytic Breakers for Use in Alkaline and High-Temperature Fracturing Fluids

Cited by 12 publications

References 8 publications

Post-fracturing treatments design to redress the damage caused by fracturing fluid polymers

Post-fracturing treatments design to redress the damage caused by fracturing fluid polymers

A review of fracturing fluid systems used for hydraulic fracturing of oil and gas wells

Chlorophyll: A Naturally Occurring Green Polymer Breaker for Hydraulic Fracturing

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