A catalyst that is used in a gas phase catalytic oxidation reaction or gas phase catalytic ammoxidation reaction of propane or isobutane, in which the catalyst contains catalyst particles each having a composite metal oxide and a support that supports the composite metal oxide, the catalyst particles have a median diameter of 20 m or more and 150 m or less, a shape of the catalyst particle is spherical, and in a binarization processed image BP.sub.2 obtained by performing a binarization process for classifying regions into a predetermined white region and a predetermined black region on a cross-sectional image showing the catalyst particles and having an area of 1200 m.sup.2 or more obtained by predetermined SEM backscattered electron image observation, /A that is calculated by a predetermined method satisfies 0.10 or more and 0.30 or less.

A catalyst that is used in a gas phase catalytic oxidation reaction or gas phase catalytic ammoxidation reaction of propane or isobutane, in which the catalyst contains catalyst particles each having a composite metal oxide and a support that supports the composite metal oxide, the catalyst particles have a median diameter of 20 m or more and 150 m or less, a shape of the catalyst particle is spherical, and in a binarization processed image BP.sub.2 obtained by performing a binarization process for classifying regions into a predetermined white region and a predetermined black region on a cross-sectional image showing the catalyst particles and having an area of 1200 m.sup.2 or more obtained by predetermined SEM backscattered electron image observation, /A that is calculated by a predetermined method satisfies 0.10 or more and 0.30 or less.

Disclosed are novel supported nanoparticle compositions, precursors, processes for making supported nanoparticle compositions, processes for making catalyst compositions, and processes for converting syngas. The catalyst composition can comprise nanoparticles comprising metal oxide(s), such as manganese cobalt oxide. This disclosure is particularly useful for converting syngas via the Fischer-Tropsch reactions to make olefins and/or alcohols.

The present invention relates to a catalyst for converting CO.sub.2 to synthetic fuel such as CO using metal oxides and a conversion method using the same. The CO.sub.2 conversion catalyst according to the present invention can treat a large amount of CO.sub.2 per unit mole and is oxidized. In the reduction cycle, the catalyst has relatively high structural stability and excellent long-term stability as a catalyst, and it has excellent activity as a CO.sub.2 decomposition catalyst that can be used in a continuous flow reactor, such as for CO.sub.2 decomposition at a relatively low temperature.

Disclosed are a preparation method and application of a 4-methyl-5-vinylthiazolyl polymerized spherical ionic liquid catalyst. The method comprises: preparing a functional ionic liquid monomer successfully by taking 4-methyl-5-vinylthiazole as the matrix, and preparing the polymerized spherical ionic liquid from the monomer. The catalyst combines the advantages of both ionic liquid and the polymer, and has the characteristics of large specific surface area, high catalytic activity, high mass transfer rate, good selectivity, high stability, easy recycling and separating, environmental friendliness, wide industrial application prospect, etc. The spherical ionic liquid is made into a novel catalytic packing and then put into a reactive distillation column for continuous reactive distillation of esterification and transesterification to realize the organic combination of the ionic liquid and the reactive distillation technology, achieving good catalytic activity, high product yield, environmental friendliness, and low corrosivity, which has great significance in realizing an environment-friendly process.

A photocatalyst filter is provided. The photocatalyst filter includes: a base in which an internal space is formed. The internal space is permeable to fluid, and a plurality of photocatalyst beads are provided in the internal space, wherein a surface of the internal space is reflective.

Processes for dehydrogenation of a hydrocarbon feedstock are described. The process can be run at lower H.sub.2/HC ratios and lower RITs while maintaining coke production at the same level as operation at higher H.sub.2/HC ratios and higher RITs without decreasing the yield per pass. Acceptable levels of coke were achieved when operating the process at low hydrogen to hydrocarbon molar ratio in the range of 0.01 to 0.40 and reactor inlet temperatures in the range of 500-645 C.

The invention relates to a core-shell structured catalyst comprising a core covered with a shell, the core is made of hematite, tourmaline, germanium, maifanite or kaolin. The invention also provides a method for preparing the catalyst including mixing raw materials of the core with water to form seed-balls with a particle size of 2-4 mm; mixing the seed-balls with raw materials of the shell and water, such that the seed-balls are covered with the raw materials of the shell to form pellets with a particle size of 3-5 mm; processing the pellets at 60-90 C. and then calcining to active the pellets at 450-550 C. to obtain a core-shell structured catalyst. The invention further discloses use of the core-shell structured catalyst in the ozone oxidation reaction. In the invention, a core-shell structured catalyst with good morphology and catalytic performance is prepared, and the production cost of the catalyst is reduced.

Nickel electrodes comprising an electrically conductive nickel sheet and a nickel layer deposited thereon which consists of spherical, porous nickel particles which adhere to each other, made by the method of partially reducing spherical nickel hydroxide particles in a reducing atmosphere at elevated temperatures to obtain partially reduced spherical Ni/NiO particles, preparing a paste from the Ni/NiO particles obtained and an organic and/or inorganic binder as well as further excipients as required, applying the paste in a layer to one or both sides of the electrically conductive nickel sheet, and tempering the coated nickel sheet in a reducing atmosphere at elevated temperatures. Self-supporting nickel layers of spherical, porous nickel particles which adhere to each other. Producing nickel electrodes and the self-supporting nickel layer, and use thereof, particularly as an electrode for water electrolysis.

A method for preparing methyl methacrylate from methacrolein and methanol; said method comprising contacting in a reactor a mixture comprising methacrolein, methanol and oxygen with a heterogeneous catalyst comprising a support and a noble metal, wherein pH at the reactor outlet is from 3 to 6.7.