Abstract: Systems and methods for treating subterranean formations using solid particulates comprising compounds having an aminopolycarboxylic functional group and a phosphoric acid functional group. In one embodiment, the methods comprise: providing a treatment fluid comprising a base fluid and a plurality of solid particulates, wherein the solid particulates comprise at least one compound having an aminocarboxylic functional group and a phosphonic functional group, and wherein the solid particulates have a diameter from about 0.1 microns to about 5 millimeters; and introducing the fluid into a wellbore penetrating a portion of a subterranean formation at a rate and pressure sufficient to create or enhance one or more fractures in the subterranean formation.

Abstract: Provided are methods for propping a fracture. An example method comprises providing a treatment fluid comprising a polyester, a water-miscible solvent, and a proppant and then pumping the treatment fluid through an aqueous fluid within a wellbore to form an amorphous polymeric web. The method further comprises pumping the amorphous polymeric web into a fracture within a subterranean formation and then allowing the amorphous polymeric web to dissolve.

Abstract: Method comprising introducing a treatment fluid into a subterranean formation, the treatment fluid comprising a pseudo-crosslinking agent and an acidic viscoelastic surfactant (AVS) base fluid, wherein the treatment fluid has a pH of less than 5. The AVS base fluid includes a zwitterionic viscoelastic surfactant, an acidic constituent, and a polar solvent and the zwitterionic viscoelastic surfactant is present in an amount in the range of from about 0.001% to about 15% by weight of active surfactant of the AVS base fluid. The treatment fluid performs a subterranean formation operation.

Abstract: Methods of treating a carbonate formation are provided. The methods include introducing a nanoparticle gel system into the carbonate formation at a rate and pressure sufficient to create or enhance at least one fracture in the carbonate formation. The nanoparticle gel system includes a gelling agent, a nanoparticle-size clay, and a proppant. The methods further include allowing a portion of the proppant to deposit in the at least one fracture, pumping an acidic fluid into the carbonate formation, and allowing a portion of the acidic fluid to at least partially reduce a viscosity of the nanoparticle gel system and to react with the carbonate formation.

Abstract: Provided are methods and systems for treating a fracture. An example method comprises providing a treatment fluid comprising a solubilized polyester and a water-miscible solvent; dispersing the treatment fluid into an aqueous fluid; wherein the dispersing the treatment fluid into an aqueous fluid precipitates the solubilized polyester and forms an amorphous polymeric structure comprising the solid polyester; introducing the amorphous polymeric structure into a fracture within a subterranean formation; and allowing the amorphous polymeric structure to degrade.

Abstract: A method my include: introducing a treatment fluid comprising a descaling agent and a carrier fluid into a wellbore, the descaling agent comprising an N-(phosphonoalkyl)iminodiacetic acid wherein the treatment fluid has a pH less than 13

Abstract: Certain metal surfaces are often unable to be contacted effectively with fluids containing hydrofluoric acid due to significant corrosion issues. Steel surfaces represent but one example. Corrosion inhibitor compositions comprising an N-(phosphonoalkyl)iminodiacetic acid or any salt thereof can be used to suppress corrosion of steel surfaces, including those that contain multiple types or grades of steel. Methods for suppressing corrosion of a steel surface can comprise: contacting a steel surface with a corrosive environment, the corrosive environment comprising hydrofluoric acid; exposing the steel surface to a corrosion inhibitor composition, the corrosion inhibitor composition comprising an N-(phosphonoalkyl)iminodiacetic acid or any salt thereof; and suppressing corrosion of the steel surface being contacted with the corrosive environment through exposure to the corrosion inhibitor composition.

Abstract: The present disclosure relates to subterranean formation operations and, more particularly, to embedded treatment fluid additives for use in subterranean formation operations. The embedded treatment additives may comprise an aqueous-soluble downhole reactive material embedded in a crosslinked polymeric solution to delay the reactivity of the aqueous-soluble downhole reactive material, thereby forming the embedded treatment additive, wherein the aqueous-soluble downhole reactive material is a solid.

Abstract: Interaction of particulates of a chelating agent with an acid-reactive surface, such as various surfaces found in a wellbore, can provide a number of benefits during a treatment process. Methods for utilizing particulates of a chelating agent in a treatment process can comprise: introducing a foamed treatment fluid having a continuous liquid phase and a discontinuous gas phase into a wellbore penetrating a subterranean formation, the foamed treatment fluid comprising: a plurality of particulates comprising an N-(phosphonoalkyl)iminodiacetic acid, and an acid in which the N-(phosphonoalkyl)iminodiacetic acid is substantially insoluble; and depositing at least a portion of the plurality of particulates at one or more locations within the subterranean formation.

Abstract: Provided are methods and systems for treating a subterranean formation. An example method comprises pumping an aerosol comprising a vaporized carrier fluid and a dispersed polyhydroxyetheramine in a wellbore penetrating the subterranean formation; depositing the polyhydroxyetheramine on a surface of the subterranean formation; and producing hydrocarbons from the treated subterranean formation.

Abstract: A well treatment fluid comprising a base fluid and a viscosifying agent for increasing the viscosity of the well treatment fluid is provided. The viscosifying agent comprises a plurality of polyhedral oligomeric silsesquioxane particles that each contain at least one reactive functional end group. A method of treating a subterranean formation penetrated by a wellbore is also provided. In one embodiment, the method of treating a subterranean formation penetrated by a wellbore is a method of fracturing a subterranean formation penetrated by a wellbore.

Abstract: Complexation of metal ions using chelating agents within a subterranean formation can often be desirable, such as to temper the formation of metal-containing precipitates. However, many chelating agents are produced commercially in an alkali metal salt form that may not be entirely suitable for use downhole, particularly in subterranean formations containing a siliceous material. The working pH range of some types of chelating agents may also be limiting. Treatment fluids comprising an aqueous carrier fluid having an acidic pH, a sulfonated iminodialkanoic acid, and ammonium ions may at least partially address downhole precipitation issues, while providing further advantages as well. Methods for forming sulfonated iminodialkanoic acids can comprise reacting an iminodialkylnitrile with a sultone under acidic conditions to form a fluid comprising a sulfonated iminodialkanoic acid and ammonium ions.

Abstract: Removing inorganic scale and other acid-soluble materials in the presence of a particulate pack can sometimes result in unwanted alterations to the particulate pack. Methods for removing inorganic scale can comprise: introducing a descaling agent comprising an N-(phosphonoalkyl)iminodiacetic acid or any salt thereof into a wellbore in fluid communication with a particulate pack, an inorganic scale being present in the wellbore or in the particulate pack; contacting the descaling agent with the particulate pack and the inorganic scale; and removing at least a portion of the inorganic scale using the N-(phosphonoalkyl)iminodiacetic acid or any salt thereof without substantially affecting the particulate pack.

Abstract: Extraneous metal ions in a source of water can often make the water unsuitable for use as the continuous phase of an aqueous fracturing fluid. Extraneous metal ions can be a particular issue for produced water and other process water sources. Methods for treating water and forming a fracturing fluid therefrom can comprise: providing a metal-laden water comprising a quantity of one or more metal ions; combining an N-(phosphonoalkyl)iminodiacetic acid or a salt thereof with the metal-laden water to form a remediated water, the remediated water comprising the N-(phosphonoalkyl)iminodiacetic acid, the salt thereof, a metal complex thereof or a combination thereof; and formulating the remediated water into a fracturing fluid comprising a gelled polymer.

Abstract: Certain metal surfaces are often unable to be effectively contacted with fluids containing hydrofluoric acid due to significant corrosion issues. Titanium and titanium alloy surfaces represent but one example. Corrosion inhibitor compositions comprising boric acid and an N-(phosphonoalkyl)iminodiacetic acid or any salt thereof can be used to suppress metal corrosion, including that taking place on titanium and titanium alloy surfaces.

Abstract: Methods for reducing viscosifying tendencies of crude oil in subterranean formations using solid acid chelating agents are described. The methods include combining a solid acid chelating agent and an aqueous acid solution to form a treatment fluid, and introducing the treatment fluid into the subterranean formation. The solid acid chelating agent includes at least one aminopolycarboxylic acid functional group and at least one phosphonic acid functional group.

Abstract: Systems and methods for treating subterranean formations using solid particulates comprising compounds having an aminopolycarboxylic functional group and a phosphoric acid functional group. In one embodiment, the methods comprise: providing a treatment fluid comprising a base fluid and a plurality of solid particulates, wherein the solid particulates comprise at least one compound having an aminocarboxylic functional group and a phosphonic functional group, and wherein the solid particulates have a diameter from about 0.1 microns to about 5 millimeters; and introducing the fluid into a wellbore penetrating a portion of a subterranean formation at a rate and pressure sufficient to create or enhance one or more fractures in the subterranean formation.

Abstract: Some sensitive metal surfaces are often unable to be contacted effectively with hydrofluoric acid or acidic fluoride ions due to significant corrosion issues that may occur. Metal surfaces comprising titanium or a titanium alloy represent but one example of sensitive metal surfaces having this issue. Corrosion inhibitor compositions comprising boric acid and other boron-containing compounds may at least partially suppress corrosion of titanium and titanium alloy surfaces. Methods for suppressing corrosion may comprise: contacting a metal surface comprising titanium or a titanium alloy with a corrosion inhibitor composition comprising a boron-containing compound; and interacting the metal surface with a fluid phase comprising hydrofluoric acid or acidic fluoride ions.

Abstract: Removing inorganic scale and other acid-soluble materials in the presence of a particulate pack can sometimes result in unwanted alterations to the particulate pack. Methods for removing inorganic scale can comprise: introducing a descaling agent comprising an N-(phosphonoalkyl)iminodiacetic acid or any salt thereof into a wellbore in fluid communication with a particulate pack, an inorganic scale being present in the wellbore or in the particulate pack; contacting the descaling agent with the particulate pack and the inorganic scale; and removing at least a portion of the inorganic scale using the N-(phosphonoalkyl)iminodiacetic acid or any salt thereof without substantially affecting the particulate pack.

Abstract: Extraneous metal ions in a source of water can often make the water unsuitable for use as the continuous phase of an aqueous fracturing fluid. Extraneous metal ions can be a particular issue for produced water and other process water sources. Methods for treating water and forming a fracturing fluid therefrom can comprise: providing a metal-laden water comprising a quantity of one or more metal ions; combining an N-(phosphonoalkyl)iminodiacetic acid or a salt thereof with the metal-laden water to form a remediated water, the remediated water comprising the N-(phosphonoalkyl)iminodiacetic acid, the salt thereof, a metal complex thereof or a combination thereof; and formulating the remediated water into a fracturing fluid comprising a gelled polymer.