A method for monitoring air quality is described. The method includes measuring ethane and methane using a mobile sensor platform to provide sensor data. The sensor data includes methane data and ethane data captured at a nonzero mobile sensor platform speed. Methane and ethane peak(s) are identified in the sensor data. Correlation(s) between the methane and ethane peak(s) and/or between the methane peak(s) and at least one amount of .sup.13C are determined. A source for the methane is determined based on the correlation.

The disclosure discloses a methane value online real-time monitoring system, which includes a laser tunable system portion, a gas component detection system portion and a data processing system portion. The laser tunable system portion includes a computer, laser drivers, tunable lasers, a laser beam combiner, a collimator, and a beam expander, which are connected in sequence. The gas component detection system portion includes a gas supply system pipeline, a hose, a valve, and a gas chamber. The data processing system portion includes a detector, lock-in amplifiers, an oscilloscope, and a data acquisition card, which are connected in sequence. In a working process of the methane value online real-time monitoring system, gas mass namely the methane value change can be monitored in real time on line by collecting natural gas introduced into a combustion chamber through a gas supply system pipeline of a natural gas engine.

There is described a system for analyzing an air condition. The system comprises a detection unit configured for detecting of detection signals indicative of a bacteria-related contamination of an evaporator and/or an air filter of the air condition, an analyzing unit configured for analyzing of a level of contamination of the evaporator and/or the air filter based on the detection signals, and an output unit configured for outputting the analyzed level of contamination of the evaporator and/or the air filter to a user.

The invention relates to a system and micro monitor apparatus, a space-, time-, and cost-efficient device to concentrate, identify, and quantify organic compounds in gas environments. The invention further relates to a method centered on gas chromatography for identifying and quantifying organic compounds in gas environments, using air as the carrier gas, without the need for a compressed pre-bottled purified carrier gas.

A gas detecting module is disclosed. A gas-inlet concave and a gas-outlet concave are formed on a sidewall of a base. A gas-inlet-groove region and a gas-outlet-groove region are formed on a surface of the base. The gas-inlet concave is in communication with a gas-inlet groove of the gas-inlet-groove region, and the gas-outlet concave is in communication a gas-outlet groove of the gas-outlet-groove region. The gas-inlet-groove region and the gas-outlet-groove region are covered by a thin film to achieve the effectiveness of laterally inhaling and discharging out gas relative to the gas detecting module.

A method for analyzing a gas, where a sensitive metal oxide-containing layer is exposed to the gas, includes: reducing the temperature of the sensitive layer from a first temperature to a second temperature, the temperature of the sensitive layer being maintained essentially at the second temperature for a predetermined time period; increasing the temperature of the sensitive layer to a third temperature; measuring at least one electrical resistance value of the sensitive layer while the sensitive layer exhibits essentially the third temperature; and analyzing components of the gas based on the measured at least one electrical resistance value.

Provided are installation devices and uses thereof for receiving and installing an adaptor body for sampling soil gas under a slab. The installation device includes a cylindrical body and an internal cavity. The cylindrical body has a length greater than a thickness of the slab, a first end configured to be placed adjacent a top of the slab, and a second end configured to be placed below a bottom of the slab. The internal cavity extends longitudinally through the cylindrical body from the first end to the second end, where the internal cavity has a first portion and a second portion. The first portion has a first diameter located at the first end of the cylindrical body and the second portion has a second diameter that is less than the first diameter. The internal cavity of the cylindrical body is configured to receive the adaptor body.

A bioelectronic sensor is disclosed for detecting presence of at least one volatile organic compound (VOC), the sensor comprising a single carbon nanotube (CNT) covalently immobilizing a single receptor optionally being a mammalian or an insect receptor, wherein association of the VOC to said receptor allows for a measurable electric field effect.

The present invention provides a method for the detection of American foulbrood (AFB) in a beehive, said method comprising the steps of taking a sample from the beehive and testing the sample for a range of compounds, wherein the presence of one or more of the compounds in a relative amount of at least three times that of a non-infected hive indicates the presence of AFB in the beehive.

Described herein are Dirofilarial exhalant signatures and methods of detecting a Dirofilaria signature in a non-blood biological sample, such as exhalant, that can be used to detect Dirofilarial infection in a subject, such as a canine.