Abstract: Provided are systems and methods for thermally-regenerative batteries that avoid solid metal dissolution and deposition reactions. A thermoelectrochemical system includes a reactor comprising first and second electrode compartments with a separator interposed between the first and second electrode compartments. The reactor further includes first and second electrodes disposed in the first and second electrode compartments, respectively. The first and second electrode compartments include first and second aqueous electrolyte solutions, respectively. The first electrode compartment, the second electrode compartment, or both include a thermally regenerative ligand and optionally a non-thermally regenerative ligand. The first and second aqueous electrolyte solutions exclude solid metal dissolution and deposition reactants. Also provided are methods of using the thermoelectrochemical systems provided herein.

Abstract: The present invention concerns a composite sealing component. The composite sealing component has a plurality of planar sealing elements 2, 3, one or more of sealing elements 2 having a higher compressibility than adjacent sealing elements 3 of relatively low compressibility. The sealing elements of relative low compressibility 3 are configured to maintain a fixed spacing to limit compression of the one or more sealing elements 2 of relatively high compressibility provided therebetween.

Abstract: Systems and methods for microbial processes of generating products such as electrical power, hydrogen gas and methane, are provided according to aspects of the present invention which include a reaction chamber having a wall defining an interior of the reaction chamber and an exterior of the reaction chamber; an anode at least partially contained within an anode compartment of the reaction chamber; a plurality of exoelectrogenic microorganisms disposed in the anode compartment; a cathode at least partially contained within a cathode compartment of the reaction chamber; a conductive conduit for electrons in electrical communication with the anode and the cathode; and a reverse electrodialysis stack comprising a plurality of plurality of alternating anion selective barriers and cation selective barriers disposed between the anode and the cathode defining one or more saline material compartments and one or more lower-saline material compartments.

Abstract: Devices for production of electricity and/or hydrogen gas are provided by the present invention. In particular, microbial fuel cells for production of electricity and modified microbial fuel cells for production of hydrogen are detailed. A tube cathode is provided which includes a membrane forming a general tube shape. An anode is provided which has a specific surface area greater than 100 m2/m3. In addition, the anode is substantially non-toxic to anodophilic bacteria. Combinations of particular anodes and cathodes are included in microbial fuel cells and modified microbial fuel cells.

Abstract: Increasing competition for fossil fuels, and the need to avoid release carbon dioxide from combustion of these fuels requires development of new and sustainable approaches for energy production and carbon capture. Biological processes for producing methane gas and capturing carbon from carbon dioxide are provided according to embodiments of the present invention which include providing an electromethanogenic reactor having an anode, a cathode and a plurality of methanogenic microorganisms disposed on the cathode. Electrons and carbon dioxide are provided to the plurality of methanogenic microorganisms disposed on the cathode. The methanogenic microorganisms reduce the carbon dioxide to produce methane gas, even in the absence of hydrogen and/or organic carbon sources.

Abstract: Systems and methods for microbial processes of generating products such as electrical power, hydrogen gas and methane, are provided according to aspects of the present invention which include a reaction chamber having a wall defining an interior of the reaction chamber and an exterior of the reaction chamber; an anode at least partially contained within an anode compartment of the reaction chamber; a plurality of exoelectrogenic microorganisms disposed in the anode compartment; a cathode at least partially contained within a cathode compartment of the reaction chamber; a conductive conduit for electrons in electrical communication with the anode and the cathode; and a reverse electrodialysis stack comprising a plurality of plurality of alternating anion selective barriers and cation selective barriers disposed between the anode and the cathode defining one or more saline material compartments and one or more lower-saline material compartments.

Abstract: A microbial fuel cell configuration of the invention includes a substrate particularly formulated for a microbial fuel cell configured to produce electricity and/or a modified microbial fuel cell configured to produce hydrogen. A substrate formulation according to one embodiment includes a solid biodegradable organic material in a package porous to bacteria. A microbial fuel cell provided according to embodiments of the present invention includes an anode, a cathode, an electrically conductive connector connecting the anode and the cathode, a housing for an aqueous medium, the aqueous medium in contact with the anode, and a solid form of a biodegradable organic substrate disposed in the aqueous medium, the solid form of a biodegradable organic substrate formulated to support electron generation and transfer to the anode by anodophilic bacteria over a selected minimum period of time.

Abstract: A wastewater treatment process and wastewater treatment device for generating current and desalting simultaneously are provided. The device may comprise an anode compartment, an anion exchange membrane, a middle desalting compartment, a cation exchange membrane and a cathode compartment. Wastewater flows into the anode compartment, and is oxidized under the action of an electricigenic microbe. In the desalting compartment, anions are transferred to the anode compartment through the anion exchange membrane, and cations are transferred to the cathode compartment through the cation exchange membrane, thus achieving a desalting process and forming an internal current. Electrons are transferred to the cathode through an external circuit such that a reduction reaction takes place and a current generation is achieved. The wastewater treatment, the current generation and the desalination are achieved simultaneously in the process.

Abstract: A system for hydrogen gas generation is provided according to the present invention which includes a hydrogen gas electrode assembly including a first anode in electrical communication with a first cathode; a microbial fuel cell electrode assembly including a second anode in electrical communication with a second cathode, the microbial fuel cell electrode assembly in electrical communication with the hydrogen gas electrode assembly for enhancing an electrical potential between the first anode and the first cathode. A single chamber housing contains the hydrogen gas electrode assembly at least partially in the interior space of the housing.

Abstract: Microbial processes and systems are provided according to the present invention for desalination of saline materials, such as aqueous mixtures including dissolved salts. Microbial desalination devices according to embodiments of the present invention create hydrogen gas in a configuration referred to as a microbial electrolysis desalination cell (MEDC), or electricity in a configuration referred to as a microbial fuel desalination cell (MFDC) in addition to desalination of saline materials.

Abstract: Methods of improving a performance parameter of a microbial fuel cell are provided according to embodiments of the present invention which include heating an electrode and exposing the heated electrode to ammonia gas to produce a treated electrode characterized by an increased positive surface charge on the electrode surface.

Abstract: An apparatus is provided according to embodiments of the present invention which includes a reaction chamber having a wall defining an interior of the reaction chamber and an exterior of the reaction chamber; exoelectrogenic bacteria disposed in the interior of the reaction chamber; an aqueous medium having a pH in the range of 3-9, inclusive, the aqueous medium including an organic substrate oxidizable by exoelectrogenic bacteria and the medium disposed in the interior of the reaction chamber. An inventive apparatus further includes an anode at least partially contained within the interior of the reaction chamber; and a brush or mesh cathode including stainless steel, nickel or titanium, the cathode at least partially contained within the interior of the reaction chamber.

Abstract: Systems and processes for producing hydrogen using bacteria are described. One detailed process for producing hydrogen uses a system for producing hydrogen as described herein, the system including a reactor. Anodophilic bacteria are disposed within the interior of the reactor and an organic material oxidizable by an oxidizing activity of the anodophilic bacteria is introduced and incubated under oxidizing reactions conditions such that electrons are produced and transferred to the anode. A power source is activated to increase a potential between the anode and the cathode, such that electrons and protons combine to produce hydrogen gas. In one system for producing hydrogen is provided which includes a reaction chamber having a wall defining an interior of the reactor and an exterior of the reaction chamber.

Abstract: Increasing competition for fossil fuels, and the need to avoid release carbon dioxide from combustion of these fuels requires development of new and sustainable approaches for energy production and carbon capture. Biological processes for producing methane gas and capturing carbon from carbon dioxide are provided according to embodiments of the present invention which include providing an electromethanogenic reactor having an anode, a cathode and a plurality of methanogenic microorganisms disposed on the cathode. Electrons and carbon dioxide are provided to the plurality of methanogenic microorganisms disposed on the cathode. The methanogenic microorganisms reduce the carbon dioxide to produce methane gas, even in the absence of hydrogen and/or organic carbon sources.

Abstract: Systems and processes for producing hydrogen using bacteria are described. One detailed process for producing hydrogen uses a system for producing hydrogen as described herein, the system including a reactor. Anodophilic bacteria are disposed within the interior of the reactor and an organic material oxidizable by an oxidizing activity of the anodophilic bacteria is introduced and incubated under oxidizing reactions conditions such that electrons are produced and transferred to the anode. A power source is activated to increase a potential between the anode and the cathode, such that electrons and protons combine to produce hydrogen gas. In one system for producing hydrogen is provided which includes a reaction chamber having a wall defining an interior of the reactor and an exterior of the reaction chamber.

Abstract: Systems and processes for producing hydrogen using bacteria are described. One detailed process for producing hydrogen uses a system for producing hydrogen as described herein, the system including a reactor. Anodophilic bacteria are disposed within the interior of the reactor and an organic material oxidizable by an oxidizing activity of the anodophilic bacteria is introduced and incubated under oxidizing reactions conditions such that electrons are produced and transferred to the anode. A power source is activated to increase a potential between the anode and the cathode, such that electrons and protons combine to produce hydrogen gas. One system for producing hydrogen includes a reaction chamber having a wall defining an interior of the reactor and an exterior of the reaction chamber. An anode is provided which is at least partially contained within the interior of the reaction chamber and a cathode is also provided which is at least partially contained within the interior of the reaction chamber.

Abstract: Methods of improving a performance parameter of a microbial fuel cell are provided according to embodiments of the present invention which include heating an electrode and exposing the heated electrode to ammonia gas to produce a treated electrode characterized by an increased positive surface charge on the electrode surface.

Abstract: A system for hydrogen gas generation is provided according to the present invention which includes a hydrogen gas electrode assembly including a first anode in electrical communication with a first cathode; a microbial fuel cell electrode assembly including a second anode in electrical communication with a second cathode, the microbial fuel cell electrode assembly in electrical communication with the hydrogen gas electrode assembly for enhancing an electrical potential between the first anode and the first cathode. A single chamber housing contains the hydrogen gas electrode assembly at least partially in the interior space of the housing.

Abstract: The present invention provides a method and system for managing regulatory information. In an embodiment, a regulatory information management system includes a facilities compliance manager and a permit manager. The facilities compliance manager enables a main screen to be displayed at the client. The main screen allows a user to manage the facility data stored in the database to ensure compliance of the facility with federal and state regulations including air, water, and waste regulations and associated permits. Menus and icons are provided for accessing Facility, Materials, Air, Waste, and Water management screens. The regulatory information management system can also include a message generator, a formula calculator, a regulatory form generator, and an environmental tool integrator.

Abstract: Devices for production of electricity and/or hydrogen gas are provided by the present invention. In particular, microbial fuel cells for production of electricity and modified microbial fuel cells for production of hydrogen are detailed. A tube cathode is provided which includes a membrane forming a general tube shape. An anode is provided which has a specific surface area greater than 100 m2/m3. In addition, the anode is substantially non-toxic to anodophilic bacteria. Combinations of particular anodes and cathodes are included in microbial fuel cells and modified microbial fuel cells.