Described herein are surfactant compositions for use in oil and gas operations. The surfactant compositions are stable under harsh conditions, including in formations that exhibit high salinity, high temperature, and/or high H2S concentration. Also provided are methods of using these compositions. Specifically an aqueous composition comprising: (i) a surfactant package, wherein the surfactant package comprises: (a) a surfactant comprising a branched, unbranched, saturated, or unsaturated C6-C32:80(0-65):PO(0-65):EO(0-100)-X having a concentration within the aqueous composition of from 0.05%-5% by weight, based on the total weight of the aqueous composition, wherein there is at least one BO, PO, or EO group, and wherein X comprises a sulfonate, a disulfonate, a carboxylate, a dicarboxylate, a sulfosuccinate, a disulfosuccinate, or hydrogen: and (b) olefin sulfonate and/or a disulfonate; and (ii) water.

Described herein are surfactant compositions for use in oil and gas operations. The surfactant compositions are stable under harsh conditions, including in formations that exhibit high salinity, high temperature, and/or high H2S concentration. Also provided are methods of using these compositions. Specifically an aqueous composition comprising: (i) a surfactant package, wherein the surfactant package comprises: (a) a surfactant comprising a branched, unbranched, saturated, or unsaturated C6-C32:80(0-65):PO(0-65):EO(0-100)-X having a concentration within the aqueous composition of from 0.05%-5% by weight, based on the total weight of the aqueous composition, wherein there is at least one BO, PO, or EO group, and wherein X comprises a sulfonate, a disulfonate, a carboxylate, a dicarboxylate, a sulfosuccinate, a disulfosuccinate, or hydrogen: and (b) olefin sulfonate and/or a disulfonate; and (ii) water.

The present invention is a surfactant composition containing (a) a branched alkyl sulfosuccinate ester having a branched alkyl group with 9 or 10 carbons and (b) a surfactant [excluding (a)].

This invention relates to stabilizer concentrates which improve the stability of mono- and/or diesters of mono- and/or diethylene glycol wax dispersions in personal care compositions, wherein the stabilizer concentrates comprising hydrogenated castor oil and betaines and are free of anionic surfactants.

The object of the present invention is to provide a stabilizer for and a method for stabilizing an emulsion composition emulsified with a non-ionic surfactant. This invention solves the above object by providing a stabilizer for an emulsion composition emulsified with a non-ionic surfactant; the stabilizer comprising a glycosyl naringenin as an effective ingredient, and a method for stabilizing an emulsion composition emulsified with a non-ionic surfactant; the method comprising a step of having a stabilizer that comprises a glycosyl naringenin as an active ingredient mixed and/or contained in a starting material of the emulsion composition, an intermediate product of the emulsion composition, and/or the emulsion composition manufactured.

The object of the present invention is to provide a stabilizer for and a method for stabilizing an emulsion composition emulsified with a non-ionic surfactant. This invention solves the above object by providing a stabilizer for an emulsion composition emulsified with a non-ionic surfactant; the stabilizer comprising a glycosyl naringenin as an effective ingredient, and a method for stabilizing an emulsion composition emulsified with a non-ionic surfactant; the method comprising a step of having a stabilizer that comprises a glycosyl naringenin as an active ingredient mixed and/or contained in a starting material of the emulsion composition, an intermediate product of the emulsion composition, and/or the emulsion composition manufactured.

A scale inhibitor squeeze treatment is enhanced by injecting a pre-flush solution into a wellbore, where the pre-flush solution includes at least one organic carbonate solvent, such as a dialkyl carbonate and/or a cyclic carbonate. The use of an organic carbonate solvent can help prevent the pre-flush solution emulsion formation, help avoid water-blocking, and enhance scale inhibitor adsorption. The use of an organic carbonate solvent also permits the pre-flush solution to be free of water, in one non-limiting embodiment.

A scale inhibitor squeeze treatment is enhanced by injecting a pre-flush solution into a wellbore, where the pre-flush solution includes at least one organic carbonate solvent, such as a dialkyl carbonate and/or a cyclic carbonate. The use of an organic carbonate solvent can help prevent the pre-flush solution emulsion formation, help avoid water-blocking, and enhance scale inhibitor adsorption. The use of an organic carbonate solvent also permits the pre-flush solution to be free of water, in one non-limiting embodiment.

Provided herein are amphoteric glycolipid biosurfactants containing an amphoteric glycolipid biological surface active molecule preparation produced by acid precipitation of culture supernatant produced by sequentially culturing Pseudomonas, Candida, and Neurospora, for instance in a fermentation medium comprising a hydrophilic carbon source and a hydrophobic carbon source. Also described are amphoteric glycolipid biological surface active molecule preparations, and methods of making such preparations. The amphoteric molecules have anionic and cationic groups; example molecules include 17-L-[(2′-O-β-D-glucopyranosyl-β-D-Glucosyl)-O-]-octadecenoic acid amine-6′,6″ diacetate, and 17-L-[(2′-O-β-D-glucopyranosamine-β-D-rhamnosyl)-O-]-octadecenoic acid-6′,6″ diacetate. The amphoteric glycolipid biosurfactant has good compatibility with other types of surfactants, high temperature resistance and salt resistance, and is suitable for use in a variety of liquid systems.

The present disclosure provides methods for forming emulsions. A method for forming an emulsion comprises: bringing a first fluid phase in contact with a second fluid phase that is immiscible with the first fluid phase to generate the emulsion comprising the plurality of droplets. The plurality of droplets may comprise (i) the first fluid phase or the second fluid phase, (ii) a first surfactant at an interface between the first fluid phase and the second fluid phase, and (iii) a second surfactant that is different than the first surfactant. Subsequent to generating the emulsion, collect or direct the plurality of droplets along a channel. Subsequent to collecting or directing the plurality of droplets along the channel, at most 5% of the plurality of droplets coalesce.