Disclosed are a hydrogen detection sensor and a method of manufacturing the same. The hydrogen detection sensor is manufactured by using hydrothermal synthesis method to synthesize a molybdenum oxide (MoO.sub.3) nanostructure, and irradiating UV light thereon to form an MoO.sub.3Pd nanocomposite comprising the molybdenum oxide nanostructure with palladium (Pd) catalyst particles, and coating the MoO.sub.3Pd nanocomposite on a substrate. As such, a visible color change from the MoO.sub.3 before and after exposure to hydrogen may be so obvious that the sensing or sensitivity of hydrogen and the long-term stability may be substantially improved. In addition, the manufacturing process is simple, and the manufacturing costs may be reduced.

Disclosed are a hydrogen detection sensor and a method of manufacturing the same. The hydrogen detection sensor is manufactured by using hydrothermal synthesis method to synthesize a molybdenum oxide (MoO.sub.3) nanostructure, and irradiating UV light thereon to form an MoO.sub.3Pd nanocomposite comprising the molybdenum oxide nanostructure with palladium (Pd) catalyst particles, and coating the MoO.sub.3Pd nanocomposite on a substrate. As such, a visible color change from the MoO.sub.3 before and after exposure to hydrogen may be so obvious that the sensing or sensitivity of hydrogen and the long-term stability may be substantially improved. In addition, the manufacturing process is simple, and the manufacturing costs may be reduced.

The invention relates to a device (1) for evaluation of at least one performance criterion of heterogeneous catalysts, comprising; at least one reactant source (2), at least one reaction zone equipped with at least one catalyst and connected to at least one reactant source (2) in such a way as to produce, in each reaction zone, a heterogeneous catalytic reaction between each catalyst present in the reaction zone and the reactant or reactants coming from each reactant source (2) connected to the reaction zone, and means for evaluation of at least one performance criterion of heterogeneous catalysts, characterized in that the device (1) further comprises a gas chromatograph and in that each reaction zone (9) is situated in an injector (8) of the gas chromatograph.

The invention relates to a device (1) for evaluation of at least one performance criterion of heterogeneous catalysts, comprising; at least one reactant source (2), at least one reaction zone equipped with at least one catalyst and connected to at least one reactant source (2) in such a way as to produce, in each reaction zone, a heterogeneous catalytic reaction between each catalyst present in the reaction zone and the reactant or reactants coming from each reactant source (2) connected to the reaction zone, and means for evaluation of at least one performance criterion of heterogeneous catalysts, characterized in that the device (1) further comprises a gas chromatograph and in that each reaction zone (9) is situated in an injector (8) of the gas chromatograph.

A sensor for detecting gaseous agents has a transducer, which includes an electrical resonant circuit that forms an antenna. The sensor further includes a sensing material that is disposed on at least a portion of the transducer. The sensing material is configured to simultaneously exhibit a capacitance response and a resistance response in the presence of a gaseous agent. The sensor may be reversible, battery free, and may require no electrical contact with a sensor reader.

A sensor for detecting gaseous agents has a transducer, which includes an electrical resonant circuit that forms an antenna. The sensor further includes a sensing material that is disposed on at least a portion of the transducer. The sensing material is configured to simultaneously exhibit a capacitance response and a resistance response in the presence of a gaseous agent. The sensor may be reversible, battery free, and may require no electrical contact with a sensor reader.

A method for quantifying carbon in carbides that allows highly precise and simple quantification of carbon in carbides. The method for quantifying carbon in the carbides includes a combustion process in which the carbides are heated together with a composite member in the presence of oxygen to oxidize the carbon in the carbides to carbon monoxide and/or carbon dioxide, and a quantification process of quantifying the carbon monoxide and/or the carbon dioxide. The composite member includes two or more metal members that have main components that are different from each other.

A method for quantifying carbon in carbides that allows highly precise and simple quantification of carbon in carbides. The method for quantifying carbon in the carbides includes a combustion process in which the carbides are heated together with a composite member in the presence of oxygen to oxidize the carbon in the carbides to carbon monoxide and/or carbon dioxide, and a quantification process of quantifying the carbon monoxide and/or the carbon dioxide. The composite member includes two or more metal members that have main components that are different from each other.

Provided is a system comprising a device that performs one or more reactions to liquid or supercritical fluid chromatograph effluents and produces molecules that are subsequently detected by a suitable detector. This allows for one to practice a method for the detection and quantification of organic molecules from a liquid chromatograph for the purpose of increasing detection limits and allowing for the universal detection of organic molecules. The linear dynamic range and molecular response are greater than those previously available.

A method for examining wear of a connector contact using atom transfer radical polymerization. Metals in the connector contact are involved in atom transfer radical polymerization. In the method, polymers are formed via atom transfer radical polymerization. An average molecular weight and a polydispersity index of the polymers are determined. The exposure of underlying metal layers of the connector contact is determined based on the average molecular weight and atom transfer radical polymerization.