Methods and systems for producing a biofuel using genetically modified sulfur-oxidizing and iron-reducing bacteria (SOIRB) are disclosed. In some embodiments, the methods include the following: providing a SOIRB that have been genetically modified to include a particular metabolic pathway to enable them to generate a biofuel; feeding a first source of ferric iron to the SOIRB; feeding sulfur, water, and carbon dioxide to the SOIRB; producing at least the first particular biofuel, a first source of ferrous iron, sulfate, excess ferric iron, and an SOIRB biomass; electrochemically reducing the excess ferric iron to a second source of ferrous iron; providing an iron-oxidizing bacteria that have been genetically modified to include a particular metabolic pathway to enable them to generate a second biofuel; producing at least the second biofuel, a second source of ferric iron, and an IOB biomass; and feeding the second source of ferric iron to the SOIRB.

Methods and systems for producing a biofuel using genetically modified sulfur-oxidizing and iron-reducing bacteria (SOIRB) are disclosed. In some embodiments, the methods include the following: providing a SOIRB that have been genetically modified to include a particular metabolic pathway to enable them to generate a biofuel; feeding a first source of ferric iron to the SOIRB; feeding sulfur, water, and carbon dioxide to the SOIRB; producing at least the first particular biofuel, a first source of ferrous iron, sulfate, excess ferric iron, and an SOIRB biomass; electrochemically reducing the excess ferric iron to a second source of ferrous iron; providing an iron-oxidizing bacteria that have been genetically modified to include a particular metabolic pathway to enable them to generate a second biofuel; producing at least the second biofuel, a second source of ferric iron, and an IOB biomass; and feeding the second source of ferric iron to the SOIRB.

The present technology provide a method of dewatering whole stillage. The addition of a xylanase in combination with a pectinase results in a wet cake with a higher dry mass. The advantage here is less energy consumption while drying.

The present disclosure is directed to core-shell nanoparticles, compositions comprising core-shell nanoparticles, and methods of their use.

The present disclosure is directed to core-shell nanoparticles, compositions comprising core-shell nanoparticles, and methods of their use.

A method and system for high rate acidification and organic solids solubilization of feedstocks such as municipal source separated organics, municipal sewage sludge, and various industrial organic wastes are disclosed. The method and system feature a completely mixed bioreactor containing hydrogen-producing microorganisms, a crossflow membrane unit or membrane module located downstream of the bioreactor, a storage tank for receiving concentrated microorganisms from the membrane unit or module, and a connection that recirculates desired quantities of biomass from the storage tank to the bioreactor. This configuration decouples the solids residence time (SRT) from the hydraulic retention time (HRT) and results in a high solubilization rate.

A method and system for high rate acidification and organic solids solubilization of feedstocks such as municipal source separated organics, municipal sewage sludge, and various industrial organic wastes are disclosed. The method and system feature a completely mixed bioreactor containing hydrogen-producing microorganisms, a crossflow membrane unit or membrane module located downstream of the bioreactor, a storage tank for receiving concentrated microorganisms from the membrane unit or module, and a connection that recirculates desired quantities of biomass from the storage tank to the bioreactor. This configuration decouples the solids residence time (SRT) from the hydraulic retention time (HRT) and results in a high solubilization rate.

Disclosed is a method for improving biological production of hydrogen from protein-containing wastewater comprising two stages: ultraviolet radiation pretreatment of protein-containing wastewater and biological production of hydrogen under a neutral pH condition and intermediate temperature condition.

Disclosed is a method for improving biological production of hydrogen from protein-containing wastewater comprising two stages: ultraviolet radiation pretreatment of protein-containing wastewater and biological production of hydrogen under a neutral pH condition and intermediate temperature condition.

Provided are methods, systems, and compositions for producing activated carbon from lignin residues produced from cellulosic or lignocellulosic biomass after hydrolysis of saccharides. The activated carbon is low in ash and sulfur, high in oxygen content and iodine number.