Provided here are zirconium-substituted hierarchical zeolite compositions and methods of preparing such catalytic compositions. One such method involves subjecting the zirconium-substituted zeolite to a framework modification process using a single template to produce a framework-modified zeolite, followed by subjecting the framework-modified zeolite to an ion exchange process to produce a hierarchical zeolite composition. Also provided are methods of catalytic cracking of hydrocarbon feedstocks using these zirconium-substituted hierarchical zeolite compositions.

The present invention relates to a process for conversion of a hydrocarbon feed comprising saturated hydrocarbon compounds to olefin products comprising contacting a hydrocarbon feed stream with a catalyst in an oxidic form of the formula M1M2M3M4O comprising metals M1, M2, M3 and M4, wherein: M1 is selected from Si, Al, Zr, and mixtures thereof; M2 is selected from Pt, Cr, and mixtures thereof; M3 is selected from W, Mo, Re, and mixtures thereof; and M4 is selected from Sn, K, Y, Yb and mixtures thereof; wherein: mass fraction of M1 is in the range of 0.1 to 0.8; mass fraction of M2 is in the range of 0.001 to 0.2; mass fraction of M3 is in the range of 0.001 to 0.2; mass fraction of M4 is in the range of 0.0001 to 0.2; and mass fraction of oxygen is in the range of 0.1 to 0.8.

The present invention relates to a process for conversion of a hydrocarbon feed comprising saturated hydrocarbon compounds to olefin products comprising contacting a hydrocarbon feed stream with a catalyst in an oxidic form of the formula M1M2M3M4O comprising metals M1, M2, M3 and M4, wherein: M1 is selected from Si, Al, Zr, and mixtures thereof; M2 is selected from Pt, Cr, and mixtures thereof; M3 is selected from W, Mo, Re, and mixtures thereof; and M4 is selected from Sn, K, Y, Yb and mixtures thereof; wherein: mass fraction of M1 is in the range of 0.1 to 0.8; mass fraction of M2 is in the range of 0.001 to 0.2; mass fraction of M3 is in the range of 0.001 to 0.2; mass fraction of M4 is in the range of 0.0001 to 0.2; and mass fraction of oxygen is in the range of 0.1 to 0.8.

Method includes heating mixture of heavy oil (API<22.3), water, and catalyst in a reactor to form pyrolyzate vapor condensable to form an oil phase lighter than the heavy oil. The feed mixture can include 100 parts by weight heavy oil, 5 to 100 parts by weight water, and 1 to 20 parts by weight solid catalyst particulates, which can include an oxide or acid addition salt of a Group 3-16 metal on a mineral support. Also, an apparatus for treating the heavy oil includes a mixing zone to prepare the emulsion, a transfer line to a pyrolysis zone; and a control system for the pyrolysis zone. Also, a process includes injecting the pyrolyzate in a treatment fluid into an injection well.

Method includes heating mixture of heavy oil (API<22.3), water, and catalyst in a reactor to form pyrolyzate vapor condensable to form an oil phase lighter than the heavy oil. The feed mixture can include 100 parts by weight heavy oil, 5 to 100 parts by weight water, and 1 to 20 parts by weight solid catalyst particulates, which can include an oxide or acid addition salt of a Group 3-16 metal on a mineral support. Also, an apparatus for treating the heavy oil includes a mixing zone to prepare the emulsion, a transfer line to a pyrolysis zone; and a control system for the pyrolysis zone. Also, a process includes injecting the pyrolyzate in a treatment fluid into an injection well.

Novel catalysts comprising nickel oxide nanoparticles supported on alumina nanoparticles, methods of their manufacture, heavy oil compositions contacted by these nanocatalysts and methods of their use are disclosed. The novel nanocatalysts are useful, inter alia, in the upgrading of heavy oil fractions or as aids in oil recovery from steam-assisted well reservoirs.

Novel catalysts comprising nickel oxide nanoparticles supported on alumina nanoparticles, methods of their manufacture, heavy oil compositions contacted by these nanocatalysts and methods of their use are disclosed. The novel nanocatalysts are useful, inter alia, in the upgrading of heavy oil fractions or as aids in oil recovery from steam-assisted well reservoirs.

A mixed metal oxide Selective Oxygen Carrier (SOC) suitable for the selective oxidation of hydrogen comprising bismuth oxides, rare earth oxides, and a dopant of Ti, Zr, and Hf and is characterizable by a high level of oxygen carrying capacity, selectivity and stability. The SOC can be synthesized using a sol gel procedure, co-precipitating salts, or the incipient wetness method. The invention includes a process of dehydrogenating a paraffin over a SOC. A SOC can also be used to catalytically crack hydrocarbons.

A mixed metal oxide Selective Oxygen Carrier (SOC) suitable for the selective oxidation of hydrogen comprising bismuth oxides, rare earth oxides, and a dopant of Ti, Zr, and Hf and is characterizable by a high level of oxygen carrying capacity, selectivity and stability. The SOC can be synthesized using a sol gel procedure, co-precipitating salts, or the incipient wetness method. The invention includes a process of dehydrogenating a paraffin over a SOC. A SOC can also be used to catalytically crack hydrocarbons.

Novel catalysts comprising nickel oxide nanoparticles supported on alumina nanoparticles, methods of their manufacture, heavy oil compositions contacted by these nanocatalysts and methods of their use are disclosed. The novel nanocatalysts are useful, inter alia, in the upgrading of heavy oil fractions or as aids in oil recovery from steam-assisted well reservoirs.