Disclosed herein are the methods of using di-cationic or di-anionic compounds, which are derived from primary amine through an aza-Michael addition with an activated olefin, in a corrosion control composition to mitigate corrosion of a surface in a water system. The disclosed methods or compositions are found to be more effective than those methods or compositions including commonly used single quaternary compounds for mitigating corrosion for a metal surface in water systems.

A method is provided for the denitrification of a substance having nitrate (NO.sub.3—) molecules therein. The method includes collecting waste organic material having fats, oils and grease (“FOG”) therein, and separating the FOG from the collected waste organic material. The FOG is mixed with a saponific reagent thereby initiating a saponification reaction to hydrolyze the FOG to fatty acid salts. A resultant FOG mixture (“RFM”) is formed having stratified layers of one or more fatty acid mixtures (“FAM”) and a glycerol fraction derived mixture (“GFDM”). The GFDM is mixed with the substance wherein heterotrophic bacteria use oxygen from the nitrate (NO.sub.3—) molecules to breakdown the GFDM thereby producing nitrogen gas.

The subject invention provides microbe-based products, as well as their use to improve oil production and refining efficiency by, for example, remediating the disposable layers in oil tanks and other oil storage units. In preferred embodiments, the microbe-based products comprise biochemical-producing yeast and growth by-products thereof, such as, e.g., biosurfactants. The subject invention can be used to remediate rag layer and/or other dissolved solid layers that form in water-oil emulsions. Furthermore, the subject invention can be used for remediating solid impurities, such as sand, scale, rust and clay, in produced water, flow-back, brine, and/or fracking fluids.

Embodiments of the present disclosure are directed to a method of producing a viscoelastic surfactant (VES) fluid, the VES fluid comprising desulfated seawater. The method of producing the VES fluid comprises adding an alkaline earth metal halide to seawater to produce a sulfate precipitate. The method further comprises removing the sulfate precipitate to produce the desulfated water. The method further comprises adding a VES and one or more of a nanoparticle viscosity modifier or a polymeric modifier to the desulfated seawater. Other embodiments are directed to VES fluids that maintain a viscosity greater than 10 cP at temperatures above 250° F.

Disclosed herein are bubble-generating electrochemical reactors, as well as a reservoir system that comprises the same, used in a process for preparing a liquid agent medium comprising an oxidant effective for sanitizing, disinfecting, and/or cleaning an object.

A reactive treatment formulation and method for treatment of waste material resulting in a more stable, entombed treated waste product. The formulation comprised of a foamable surfactant that is granular and sodium percarbonate. A multi-part formulation can be delivered in a multi-compartment vessel that cooperates with a dispensing mechanism for a self-contained non-contact agitating toilet. The reactive treatment formulation prevents odors, bacterial growth, and stabilizes waste to reduce spillage during disposal.

A method for reducing fouling in an aqueous system of an olefin production plant is disclosed. The method includes adding an effective amount of a surfmer to the aqueous system, wherein the surfmer forms a water soluble adduct by covalently bonding to one or more fouling precursor compounds formed during olefin production.

Various aspects of this disclosure relate to toilet systems that include compositions to inhibit wastewater from freezing in a waste tank of a toilet. A first fluid treatment composition comprises a salt that is introduced into the waste tank. A second fluid treatment composition is a solid composite that also comprises a salt and that is introduced into a urinal in fluid communication with the waste tank.

Embodiments of the present disclosure are directed to a method of producing a viscoelastic surfactant (VES) fluid, the VES fluid comprising desulfated seawater. The method of producing the VES fluid comprises adding an alkaline earth metal halide to seawater to produce a sulfate precipitate. The method further comprises removing the sulfate precipitate to produce the desulfated water. The method further comprises adding a VES and one or more of a nanoparticle viscosity modifier or a polymeric modifier to the desulfated seawater. Other embodiments are directed to VES fluids that maintain a viscosity greater than 10 cP at temperatures above 250 F.

The disclosure provides a molecular sieve/fiber composite material comprising molecular sieves and a fiber, the molecular sieves are distributed on the fiber surface and directly contact the fiber surface; the particle diameter D90 of the molecular sieves is 0.01 to 50 m, the particle size D50 of the molecular sieves is 0.005 to 25 m; the molecular sieves are distributed uniformly on the fiber surface of the fiber. The disclosure also provides a preparation method for the molecular sieve/fiber composite material and various applications. The molecular sieve/fiber composite material has high strength, elastic recovery ability, and dimensional stability, making the composite material strong and durable. The molecular sieve/fiber composite material has a simple structure, low cost, strong stability, high repeatability of performance, and high practical efficiency, and provides the application in the fields of hemostasis, beauty, deodorization, sterilization, water purification, air purification, and radiation resistance.