Devices and methods for detecting an analyte in a gas involve the use of plasmonic excitation of a nanostructured sensing element that is tuned to absorb at a narrow bandwidth specific for light absorbed by the analyte. The sensing element can be used as a capacitive or inductive element in a circuit.

Disclosed is an apparatus and method for analyzing an evolved gas, wherein the precision of detection of a gas component is improved without enlarging the apparatus. The apparatus includes a gas component evolving unit, a detection member for detecting the gas component, and a mixed gas channel for allowing a mixed gas containing the gas component and carrier gas to flow therethrough, and further includes a branch channel branched from the mixed gas channel, an inert gas channel for allowing an inert gas to flow therethrough, a first flow rate regulator for adjusting the flow rate of the carrier gas, a second flow rate regulator for adjusting the flow rate of the inert gas, and a flow rate control unit for controlling the second flow rate regulator such that the flow rate of the mixed gas guided to the detection member is a predetermined value.

The present disclosure relates to methods, devices, and systems for measuring nitric oxide released from a material. For example, a method of measuring nitric oxide release from a material can include introducing a continuous flow of a carrier gas into a sample holding chamber via a carrier gas inlet at an effective flow rate, introducing an amount of the nitric oxide releasing material into the sample holding chamber via a separate sample inlet to contact the continuous flow of the carrier gas, directing the carrier gas and released nitric oxide out of the sample holding chamber via a nitric oxide outlet toward a nitric oxide detector, and quantifying an amount of released nitric oxide using the nitric oxide detector.

The present disclosure is directed to methods and systems for creating a gas curtain inlet for a detector of a substance of interest. The methods and systems include introducing a carrier gas into an inlet to block out atmospheric air without having to make the inlet a sealed system.

A gas-analysis sample injection system and method for transfer of sample gas from a gas-sample cylinder to an analyzer such as a gas chromatograph, providing a cabinet with a door and a cabinet vent, vent manifold, and vent exhaust, a carrier gas supply, a sample cylinder support bracket, a sample filter housing, and a sample injector valve with an injector-valve actuator. Controlled by a valve controller over valve-control lines, a carrier gas regulating valve and sample-cylinder inflow valve allow carrier gas at regulated pressure into the mounted gas-sample cylinder, and a sample-cylinder outflow valve and sample transfer valve allow flow of sample gas into the sample injector valve. A filter vent valve and injector-valve vent valve operate in coordination with the other valves to provide venting and purging of extraneous gasses.

A breathing air laboratory on location gas sample test and data collecting system and method, at a remote breathing air provider's facility, that includes an air compressor, for remotely testing, collecting, and monitoring the quality and purity of the breathing air being produced at the provider's facility, that allows an accredited independent monitoring, testing, and analyzing facility to provide breathing air validation and certification to a cloud-based air quality test and analysis account belonging to the breathing air provider facility at any time. The system includes redundant gas sample air sensors for O2 and CO to ensure quality and accuracy in the breathing air test and data collection, and analysis and a “canary” gas sample test module securely mounted in a laboratory chassis, but manually swappable, to ensure credibility and accuracy of the sensors being used to test gas/air samples.

A thermal analysis of samples and proposes a device for a thermal analysis of a sample, having: a sample chamber for receiving a sample crucible including a crucible cover attached thereto, in the interior of which a sample to be analyzed is located, wherein the sample chamber has a chamber opening for introducing the sample crucible into the sample chamber; a temperature control mechanism for controlling the temperature of the sample chamber; a measuring mechanism for measuring a temperature of the sample and one or several further measured variables; a gas conveying mechanism for creating a gas atmosphere in the sample chamber; a chamber cover, which can be attached to the chamber opening of the sample chamber; and a piercing mechanism equipped with a needle, which is suitable to pierce a hole into the crucible cover of the sample crucible by means of the needle when the sample crucible is received in the sample chamber and when the chamber cover is attached to the chamber opening. A corresponding method for a thermal analysis of a sample, a sample crucible including a crucible cover, as well as a covering/piercing unit are further proposed as part of the invention.

Perfume compositions having controlled spatio-temporal olfactory profiles are described. The disclosure also relates also to a method of measuring said spatial-temporal olfactory profiles of said compositions.

Perfume compositions having controlled spatio-temporal olfactory profiles are described. The disclosure also relates also to a method of measuring said spatial-temporal olfactory profiles of said compositions.

A breathing air laboratory on location gas sample test and data collecting system and method, at a remote breathing air provider's facility, that includes an air compressor, for remotely testing, collecting, and monitoring the quality and purity of the breathing air being produced at the provider's facility, that allows an accredited independent monitoring, testing, and analyzing facility to provide breathing air validation and certification to a cloud-based air quality test and analysis account belonging to the breathing air provider facility at any time. The system includes redundant gas sample air sensors for O2 and CO to ensure quality and accuracy in the breathing air test and data collection, and analysis and a “canary” gas sample test module securely mounted in a laboratory chassis, but manually swappable, to ensure credibility and accuracy of the sensors being used to test gas/air samples.