A catalyst for treating an exhaust gas comprising SO.sub.2, NO.sub.x and elemental mercury in the presence of a nitrogenous reductant comprises a composition containing oxides of: (i) Molybdenum (Mo) and optionally Tungsten (W); and (ii) Vanadium (V); and (iii) Titanium (Ti); and(iv) Phosphorus (P), wherein, with respect to the total metal atoms in the composition, the composition comprises: (i) Mo in an amount of less than 2 at. %, and optionally up to 9 at. % W; (ii) from 2.5 to 12 at. % V; (iii) from 85 to 96 at. % Ti, and wherein the composition comprises (iv) P in an atomic ratio to the sum of atoms of Mo, W and V of from 1:2 to 3:2. The values expressed must total 100%.

The application provides articles, systems, and methods for adsorbing and desorbing nitrogen oxides (NO.sub.x) at desired temperatures. The catalytic article comprises a NO.sub.x adsorber composition comprising a platinum group metal (PGM) component disposed on or impregnated in a support material, and a substrate, wherein the catalytic article further comprises a magnetic material capable of inductive heating in response to an applied alternating electromagnetic field. The catalytic article further comprises a conductor associated therewith for receiving current and generating an alternating electromagnetic field in response thereto, wherein the conductor is positioned such that the generated alternating electromagnetic field is applied to at least a portion of the magnetic material. This field can inductively heat the magnetic material to heat the NO.sub.x adsorber composition to desorb the NO.sub.x from the NO.sub.x adsorber composition.

A catalyst for treating fuel combustion exhaust, the catalyst comprising the following components: (i) an oxide support comprising silicon oxide, aluminum oxide, or combination of silicon and aluminum oxides; (ii) cerium oxide, zirconium oxide, or a combination of cerium and zirconium oxides in contact with said oxide support; and (iii) nanoparticles comprising elemental palladium or platinum in contact with at least component (ii), wherein said palladium or platinum is present in an amount of 0.1-4 wt. % by weight of the particles, and wherein surfaces of said nanoparticles of elemental palladium or palladium are exposed and accessible to said fuel combustion exhaust. Methods of producing and using the catalyst are also described.

An exhaust purification system for an internal combustion engine provided with an SO.sub.X storing and releasing catalyst and a particulate filter arranged downstream of the SO.sub.X storing and releasing catalyst. SO.sub.X release processing is performed for releasing SO.sub.X stored in the SO.sub.X storing and releasing catalyst. The SO.sub.X released by the SO.sub.X release processing is supplied to the particulate filter. The larger a time integral showing a sum of products of a temperature of the particulate filter and a time during which it is maintained at that temperature from when SO.sub.X release processing was performed, or the greater the number of times the filter regeneration processing is performed, the greater the concentration of SO.sub.X released by the SO.sub.X release processing.

Oxygen is effectively removed from hydrocarbon-containing gas streams while minimizing danger of explosion by contacting the gas stream with a catalyst comprising shaped bentonite supports having an outer shell containing catalytic metals gold, and at least one of palladium platinum, rhodium, or iridium.

The present invention relates to an average-density-adjustable structure and more specifically provides a structure the average density of which is adjusted by changing the material of the structure and the size of a void formed therein and which can thereby float on the surface of or in a liquid and can easily bond with or change a material present in a gas or liquid by being equipped with a first material, which is one among an organic catalyst, an inorganic catalyst, a microorganism, and a biomolecule.

Disclosed are nanostructures such as carboxysomes that encapsulate RubisCO and carbonic anhydrase to provide a protected environment to maximize CO.sub.2 assimilation. Conditions are disclosed were RubisCO can be sequestered into a variety of self-assembling nanotubes. The encapsulated protein was enzymatically active and was clearly associated with the nanotubes and removed from solution based on a number of criteria. These nanostructures were also found to enhance the stability of RubisCO toward proteases and other environmental factors. These structures can be used in scalable CO.sub.2 conversions and other processes.

Provided is a catalyst block for cleaning exhaust gas, having: a square-shaped honeycomb core provided with first-fourth outside surfaces; a first plate attached to the first outside surface; a second plate attached to the second outside surface; and an exterior frame disposed along the outer periphery of the firm and solid honeycomb core formed from the honeycomb core, the first plate and the second plate, the exterior frame being provided with a recessed part that at least encases the first plate, the second plate, the third outside surface and the fourth outside surface. In the catalyst block, a catalyst is supported in the honeycomb core, the first plate and the second plate, and the catalyst is not supported in the exterior frame.

A zeolite has a CHA structure, a SiO.sub.2/Al.sub.2O.sub.3 composition ratio less than 15, and potassium in an amount of about 0.1% by mass to about 1% by mass in terms of K.sub.2O.

A catalytic converter includes a catalyst. The catalyst includes a support, platinum group metal (PGM) particles dispersed on the support, and a barrier formed on the support. The barrier is disposed between a first set of the PGM particles and a second set of the PGM particles to suppress aging of the PGM particles.