A plant for treating fluid products obtained from an oil well, to produce a hydrocarbon product, comprises a series of separators at progressively lower pressures, to which the fluid products are supplied in succession. A high pressure gas phase is obtained from the separator and is supplied to a flow restrictor so as to undergo cooling through the Joule Thomson effect, and then passed to a NGL separator to produce a natural gas liquid stream and a gaseous natural gas stream. The natural gas stream is then processed chemically, using a synthesis gas production unit, and a Fischer-Tropsch synthesis unit to produce a synthetic crude oil. The synthetic crude oil is supplied to one of the separators, and the natural gas liquid stream is supplied to another of the separators; the pressure in the one separator is greater than the pressure in the other separator.

The present invention concerns the production and use of feedstock streams. Specifically, the present invention provides a process for the production of a commodity using two or more feedstock streams. Each feedstock stream is processed into a common intermediate and subsequently processed into a final product, such as electrical energy, a liquid fuel or a liquefied fuel, such as methanol, dimethyl ether, synthetic gasoline, diesel, kerosene, or jet fuel. The common intermediate may be synthetic gas (syngas), producer gas or pyrolysis gas.

The invention includes a system for producing a carbon dioxide conversion product, where the system includes a carbon dioxide gas source providing carbon dioxide; a delivery system for the carbon dioxide in fluid communication with the carbon dioxide gas source, wherein the delivery system delivers the carbon dioxide gas into a plasma reactor, and wherein the plasma reactor energizes the carbon dioxide gas as a plasma to produce activated carbon dioxide species; a secondary reactant source providing a secondary reactant in a secondary reactant stream that is separated from the carbon dioxide gas, wherein the secondary reactant stream is directed to contact the activated carbon dioxide species in a reaction zone, and wherein the contact between the activated carbon dioxide species and the secondary reactant in the reaction zone produces a reaction that yields the carbon dioxide conversion product. The invention also includes methods of the use of such a system for producing a carbon dioxide conversion product.

A method of chemical extraction from an aqueous solution includes receiving an aqueous solution including dissolved inorganic carbon. The method also includes increasing a pH of a first portion of the aqueous solution to form a basic solution. The basic solution is then combined with a second portion of the aqueous solution to precipitate calcium salts. The calcium salts are then collected.

A method of synthesizing fuel from an aqueous solution includes pumping the aqueous solution, containing dissolved inorganic carbon, from a body of water into a carbon extraction unit. The method further includes extracting the dissolved inorganic carbon from the aqueous solution to create CO.sub.2 by changing a pH of the aqueous solution in the carbon extraction unit. The CO.sub.2 derived in the carbon extraction unit is received by a fuel synthesis unit, and the CO.sub.2 is converted into fuel including at least one of a hydrocarbon, an ether, or an alcohol using the fuel synthesis unit.

A process for producing a Fischer-Tropsch synthesis catalyst according to the present invention comprises a step of calcining a carrier precursor containing silica calcined at a temperature T.sub.1 and a zirconium compound at a temperature T.sub.2 to obtain a carrier; and a step of calcining a catalyst precursor containing the carrier and a cobalt compound and/or a ruthenium compound at a temperature T.sub.3, wherein the content of the zirconium compound in the carrier precursor is 0.01 to 7% by mass in terms of zirconium oxide based on the total mass of the catalyst, and T.sub.1, T.sub.2, and T.sub.3 satisfy conditions represented by expressions (1) to (3):
T.sub.1≧T.sub.3  (1)
250° C.≦T.sub.2≦450° C.  (2)
250° C.≦T.sub.3≦450° C.  (3).

A process for producing a Fischer-Tropsch synthesis catalyst according to the present invention comprises a step of calcining a carrier precursor containing silica calcined at a temperature T.sub.1 and a zirconium compound at a temperature T.sub.2 to obtain a carrier; and a step of calcining a catalyst precursor containing the carrier and a cobalt compound and/or a ruthenium compound at a temperature T.sub.3, wherein the content of the zirconium compound in the carrier precursor is 0.01 to 7% by mass in terms of zirconium oxide based on the total mass of the catalyst, and T.sub.1, T.sub.2, and T.sub.3 satisfy conditions represented by expressions (1) to (3):
T.sub.1≧T.sub.3  (1)
250° C.≦T.sub.2≦450° C.  (2)
250° C.≦T.sub.3≦450° C.  (3).

The disclosed subject matter presents a catalyst or catalyst composition as well as the methods of making and using the catalyst or catalyst composition. In one aspect, the disclosed subject matter relates to a catalyst comprising CoMn.sub.aSi.sub.bX.sub.cY.sub.dO.sub.x wherein in X comprises an element from Group 11; Y comprises an element from Group 12; a ranges from 0.8 to 1.2; b ranges from 0.1 to 1; c ranges from 0.01 to 0.05; d ranges from 0.01 to 0.05; x is a number determined by the valency requirements of the other elements present; and wherein the catalyst converts synthesis gas to at least one olefin.

A process for producing syngas in a first reactor, the process comprising: feeding carbon dioxide, hydrogen and first hydrocarbons into the first reactor; at least partially oxidizing the first hydrocarbons in the first region of the first reactor; producing syngas from the carbon dioxide, hydrogen and the oxidized first hydrocarbons in a second region of the first reactor.

A catalyst, including: a transition metal; and an organic solvent. The transition metal is dispersed in the organic solvent in the form of monodisperse nanoparticles; the transition metal has a grain size of between 1 and 100 nm; and the catalyst has a specific surface area of 5 and 300 m.sup.2/g. The invention also provides a method for preparing a catalyst, including: 1) dissolving an organic salt of a transition metal in an organic solvent including a polyhydric alcohol, to yield a mixture; and 2) heating and stirring the mixture in the presence of air or inert gas, holding the mixture at the temperature of between 150 and 250° C. for between 30 and 240 min, to yield the catalyst.