There are provided a catalyst composition for producing hydrocarbons and a method for producing hydrocarbons which exhibit a high CO conversion rate, generates minimal amount of gaseous components, and is also capable of efficiently obtaining, from a syngas, a gasoline fraction which is selective for and rich in the components having a high octane number, such as aromatic, naphthenic, olefinic and branched paraffinic hydrocarbons, by using a Fischer-Tropsch synthesis catalyst that contains at least one type of metal exhibiting activity in Fischer-Tropsch reaction and manganese carbonate and a zeolite serving as a solid acid.

The present disclosure is directed to processes using a new crystalline molecular sieve designated SSZ-96, which is synthesized using a 1-butyl-1-methyl-octahydroindolium cation as a structure directing agent.

This disclosure relates to a new crystalline microporous silicate solid, designated CIT-10, comprising a two dimensional layered structure, having an organic interlayer sandwiched between individual crystalline silicate layers. This CIT-10 material can be converted to a pure-silicate of RTH topology, as well as two new of pillared silicate structures, designated CIT-11 and CIT-12. This disclosure characterizes new materials and provides methods of preparing and using these new crystalline microporous solids.

Processes are disclosed for the production of liquefied petroleum gas (LPG) hydrocarbons, utilizing both alcohol (e.g., methanol) synthesis and in situ dehydration of the alcohol to hydrocarbons, and particularly propane and/or butane. The strategic implementation of water and/or heat removal, as well as adjustments to amounts of water and/or heat removed, have been discovered to result in important process improvements, such as in the performance of catalyst systems used in these processes. Performance advantages may reside, for example, in increased LPG hydrocarbon yield and/or selectivity, increased catalyst stability, or, for a given LPG synthesis reactor, decreased exotherm and/or decreased maximum temperature. Performance parameters associated with reduced reaction temperatures may advantageously facilitate the use of a wider selection of reaction systems, such as a fluidized bed reactor, which may further improve material and heat distribution, and therefore overall process control.