Embodiments of the present disclosure describe a zeolite-like metal-organic framework composition comprising a metal-organic framework composition with ana topology characterized by the formula [M.sup.III(4, 5-imidazole dicarboxylic acid).sub.2X(solvent).sub.a].sub.n wherein M.sup.III comprises a trivalent cation of a rare earth element, X comprises an alkali metal element or alkaline earth metal element, and solvent comprises a guest molecule occupying pores. Embodiments of the present disclosure describe a method of separating paraffins comprising contacting a zeolite-like metal-organic framework with ana topology with a flow of paraffins, and separating the paraffins by size.

The present disclosure relates to a reforming catalyst and a process for preparing the same. The acidic functionality of the catalyst is suppressed by using a chloride free alumina and coating the chloride free alumina with Group V B metal oxide in the catalyst, which helps in minimizing the cracking reactions and achieving higher selectivity for liquid hydrocarbons and aromatic hydrocarbons.

A process for the steam reforming of hydrocarbons comprises partially oxidizing a feedgas comprising a hydrocarbon feedstock with an oxygen-containing gas in the presence of steam to form a partially oxidized hydrocarbon gas mixture at a temperature >1200 C. and passing the resultant partially oxidized hydrocarbon gas mixture through a bed of steam reforming catalyst, wherein the bed comprises a first layer and a second layer, each layer comprising a catalytically active metal on an oxidic support wherein the oxidic support for the first layer is a zirconia.

Provided are a photocatalyst having higher activity for hydrogen production through water splitting and a photoelectrode comprising the photocatalyst. The photocatalyst for water splitting of the present invention comprises a Ga selenide, an AgGa selenide, or both thereof.

A reactor and process for production of hydrogen gas from a carbon-containing fuel in a reaction that generates carbon dioxide is described. The carbon-containing fuel can be, for example, carbon monoxide, alcohols, oxygenates bio-oil, oil and hydrocarbons. In preferred embodiments, the reactor includes a monolithic structure form with an array of parallel flow channels. Methods of using the reactor are also described. In the reactor apparatus of the present invention, the catalytic reaction for hydrogen formation is conducted in conjunction with a carbonation reaction that removes carbon dioxide that is produced by the reactor. The carbonation reaction involves reaction of the carbon dioxide produced from the hydrogen formation reaction with metal oxide-based sorbents. The reactor apparatus can be periodically regenerated by regeneration of the sorbent. A carbon dioxide sorbent system comprising a solid sorbent and a eutectic, mixed alkali metal molten phase is also described.

In one aspect, the disclosure relates to catalytic phase transfer sorbents (PTS) for producing hydrogen-enriched syngas from a carbonaceous feedstock, the PTS comprising a formula selected from ABO.sub.3 and A.sub.n+1B.sub.nO.sub.3n+1, wherein A comprises one or more alkali metals or alkaline earth metals, wherein B comprises one or more transition metals, and wherein X comprises an anion. Also disclosed is a system for hydrogen generation from carbonaceous feedstocks, the system comprising a gasifier unit for production of H.sub.2-rich syngas and a regenerator unit for regeneration of spent PTS. Further disclosed herein is a method for hydrogen generation from carbonaceous feedstocks using the disclosed systems. The disclosed systems can be operated isothermally through 10 or more cycles without degradation in performance, while the disclosed methods can yield 50% or more H.sub.2 relative to carbon-containing species. In some aspects, the methods produce little to no CO.sub.2.

A method for producing syngas is provided, which comprises providing a feed stream comprising H.sub.2 and CO.sub.2; heating the feed stream in a first heat exchanger to provide a first heated feed stream, which is introduced into a first RWGS reactor and subjected to a first catalytic RWGS reaction in the presence of a non-methanation promoting catalyst, thereby obtaining a first syngas containing stream, which is cooled in the first heat exchanger against the feed stream, thereby obtaining a first cooled syngas stream, which is separated in a first gas/liquid separator thereby obtaining a first water-enriched stream and a first water-depleted syngas stream; heating the first water-depleted syngas stream in a second heat exchanger thereby obtaining a heated first water-depleted syngas stream, which is introduced into a second RWGS reactor and subjected to a second catalytic RWGS reaction in the presence of a non-methanation promoting catalyst.

A method for providing Closed Loop Reformation (CLR) based synthesis gas (syngas) production processes and systems where the metal oxidation and reduction systems are decoupled from the system and process thereby avoiding the closed and coupled loop metal oxidation and reduction systems used with prior art CLR based syngas production processes and systems, and the high temperature complexities associated with prior art CLR based syngas production processes and systems.

Provided is a method for preparing a catalyst for a dehydrogenation reaction of formate and a hydrogenation reaction of bicarbonate, the method including: adding a silica colloid to a polymerization step of polymerizing aniline and reacting the resulting mixture to form a poly(silica-aniline) composite; carbonizing the corresponding poly(silica-aniline) composite under an atmosphere of an inert gas; removing silica particles from the corresponding poly(silica-aniline) composite to form a polyaniline-based porous carbon support; and fixing palladium particles on the corresponding polyaniline-based porous carbon support to prepare the catalyst.

The invention relates to the use of a reactor, methods, and devices for the quantitative recovery of molecular hydrogen from solid, liquid, or gaseous substances which contain hydrogen and which have heteroatoms, as well as to reactors. In this case, the reactors have material containing chromium. The subject matter of the invention also includes the use of the reactor, the method, and the device for the compound-specific or component-specific measurement of the isotope ratio (.sup.2H) of hydrogen using online apparatuses.