Abstract: Disclosed in certain embodiments are methods of removing water, mercaptans, C5+ or C6+ hydrocarbons, or any combination thereof from a gas feed stream during an adsorption step of an adsorption cycle.

Abstract: Embodiments include methods of making a fabric laminates including depositing a first and a second columns of discrete adhesive masses on a first layer of fabric, wherein the first and second columns of discrete adhesive masses are separated by a first gap area, and placing a second layer of fabric on the first layer of fabric sandwiching the first and second columns of discrete adhesive masses, and applying pressure to all layers to form a fabric laminate structure while maintaining the first gap area unobstructed and forming a tunnel area between the first gap area and the first and second fabric layers. In some embodiments, ribbons may be pulled through the tunnels. In some embodiments, the tunnels include batting material. In some embodiments, films are placed on the first or second fabric layer and they imprint their surface finish onto the discrete adhesive masses wetting the surface of the fabric layers.

Abstract: Embodiments include methods of making a fabric laminates including depositing a first and a second columns of discrete adhesive masses on a first layer of fabric, wherein the first and second columns of discrete adhesive masses are separated by a first gap area, and placing a second layer of fabric on the first layer of fabric sandwiching the first and second columns of discrete adhesive masses, and applying pressure to all layers to form a fabric laminate structure while maintaining the first gap area unobstructed and forming a tunnel area between the first gap area and the first and second fabric layers. In some embodiments, ribbons may be pulled through the tunnels. In some embodiments, the tunnels include batting material. In some embodiments, films are placed on the first or second fabric layer and they imprint their surface finish onto the discrete adhesive masses wetting the surface of the fabric layers.

Abstract: Disclosed in certain embodiments are methods of removing water from a gas feed stream comprising mercaptans and water during an adsorption step of an adsorption cycle.

Abstract: Disclosed in certain embodiments are methods of removing water from a gas feed stream comprising hydrocarbons and water during an adsorption step of an adsorption cycle.

Abstract: Disclosed in certain embodiments are methods of removing water from a gas feed stream comprising hydrocarbons and water during an adsorption step of an adsorption cycle.

Abstract: Biogenic sulfide production is synergistically inhibited by treating sulfate-reducing bacteria (SRB) with a biocide and a metabolic inhibitor. The biocide directly kills a first portion of the SRB. The metabolic inhibitor inhibits sulfate-reducing growth of a second portion of the SRB without directly killing the second portion of the SRB. The treatment of SRB with both a biocide and a metabolic inhibitor provides effective biogenic sulfide inhibition at significantly lower concentrations than would be required if the biocide or metabolic inhibitor was used alone.

Abstract: The present invention relates to lipoparticles. The invention also relates to producing lipoparticles. The invention further relates to lipoparticles comprising a viral structural protein. The invention further relates to a lipoparticle comprising a membrane protein, and the lipoparticle can be attached to a sensor surface. The invention further relates to methods of producing and using the lipoparticle to, inter alia, assess protein binding interactions.

Abstract: Biogenic sulfide production is synergistically inhibited by treating sulfate-reducing bacteria (SRB) with a biocide and a metabolic inhibitor. The biocide directly kills a first portion of the SRB. The metabolic inhibitor inhibits sulfate-reducing growth of a second portion of the SRB without directly killing the second portion of the SRB. The treatment of SRB with both a biocide and a metabolic inhibitor provides effective biogenic sulfide inhibition at significantly lower concentrations than would be required if the biocide or metabolic inhibitor was used alone.

Abstract: Biogenic sulfide production is synergistically inhibited by treating sulfate-reducing bacteria (SRB) with a biocide and a metabolic inhibitor. The biocide directly kills a first portion of the SRB. The metabolic inhibitor inhibits sulfate-reducing growth of a second portion of the SRB without directly killing the second portion of the SRB. The treatment of SRB with both a biocide and a metabolic inhibitor provides effective biogenic sulfide inhibition at significantly lower concentrations than would be required if the biocide or metabolic inhibitor was used alone.

Abstract: Biogenic sulfide production is synergistically inhibited by treating sulfate-reducing bacteria (SRB) with a biocide and a metabolic inhibitor. The biocide directly kills a first portion of the SRB. The metabolic inhibitor inhibits sulfate-reducing growth of a second portion of the SRB without directly killing the second portion of the SRB. The treatment of SRB with both a biocide and a metabolic inhibitor provides effective biogenic sulfide inhibition at significantly lower concentrations than would be required if the biocide or metabolic inhibitor was used alone.