The present invention provides a method for forming a history of natural gas accumulation by using carbon isotopes by a pyrolysis experiment. The method includes: obtaining activation energy distribution and a frequency factor of light carbon methane; carrying out carbon isotope kinetics simulation of natural gas in a study area by using a spreadsheet function of Excel to obtain activation energy, a mass fraction and a frequency factor of heavy carbon methane; establishing a burial history and a thermal history of the study area based on geological data; and combining the activation energy distribution and frequency factor of the heavy carbon methane with the burial history and thermal history of the study area, and establishing an instantaneous curve, a cumulative curve and a stage cumulative curve of natural gas under geological conditions on a geologic time scale.

According to one embodiment, a sensor includes a base, first and second detection element portions, first to third resistor terminals, and first and second conductive terminals. The base includes first and second base regions. The first detection element portion is provided at the first base region. The first detection element portion includes a first detection dement. The first detection dement includes a first resistance member and a first conductive member. The first resistance member includes a first resistance portion and other portion. The first conductive member includes a first conductive portion and other portion. The second detection element portion is provided at the second base region. The second detection dement portion includes a second detection element. The second detection element includes a second resistance member and a second conductive member. The second resistance member includes a second resistance portion and other portion. The second conductive member includes a second conductive portion and other portion.

A gas detector detects difluoromethane present in a remote target space. The gas detector includes a detection portion that detects the difluoromethane by using absorption of light of a predetermined wavelength. The predetermined wavelength is in a wavelength range of any of a first wavelength range of 1659 to 1673 nm, a second wavelength range of 1724 to 1726 nm, a third wavelength range of 2218 to 2221 nm, a fourth wavelength range of 2463 to 2466 nm, a fifth wavelength range of 3316 to 3318 nm, and a sixth wavelength range of 9034 to 9130 nm.

Method for determining a concentration of one or more polyhalogenated compounds in a gas. The method comprises the steps of exposing at least one sampler (10) containing or constituted by a material (14) comprising a polymer matrix that is suitable for absorbing one or more polyhalogenated compounds, and a filler that is suitable for absorbing and adsorbing one or more polyhalogenated compounds which is distributed through said polymer matrix, to gas (12) containing one or more polyhalogenated compounds during a sampling period, whereby said gas (12) constitutes at least part of said gas whose concentration of one or more polyhalogenated compounds is to be determined, determining an amount of one or more polyhalogenated compounds adsorbed or absorbed by said material, (14), and calculating a concentration of one or more polyhalogenated compounds in said gas (12) to which said material (14) was exposed, either upstream or downstream of said at least one sampler (10).

The present invention relates to a method and system for measuring total chloride content in a process product stream. In particular, the present invention relates to a method of measuring hydrogen chloride and organochloride content, in situ, for a gaseous refinery process product stream. This method allows for measurement of hydrogen chloride and organochloride content in a single test method, which allows for optimised performance and maintenance schedules for chloride guard beds used within the refinery process.

The present invention is directed to an air spring having a flexible member which collapses into the form of a double meniscus under conditions where there is a substantial or a complete loss of air pressure. The double meniscus prevents the flexible member from rolling over the piston and/or chafing against surrounding parts of the vehicle on which the air spring is mounted. This is accomplished by incorporating a flexible member having a top portion, a bottom portion, and an expansion region between the top portion and the bottom portion of the flexible member, wherein the top portion is at least 10% larger in diameter than the bottom portion of the flexible member. The present invention more specifically discloses an air spring comprising a piston, a top plate, and a flexible member which is affixed to the piston and the top plate, wherein the piston, the top plate and the flexible member defines a pressurizable chamber, wherein the flexible member is comprised of a top portion, a bottom portion, and an expansion region extending between the top portion and the bottom portion of the flexible member, wherein the top portion has a diameter which is at least 10% larger than the diameter of the bottom portion.

The present technology provides an illustrative hydrofluorocarbon (HFC) detection device that includes a decomposition component, a charged particle filter, and a sensing component. The decomposition component is configured to irradiate a gas sample with a radioactive element to decompose HFC gas under conditions sufficient to form hydrogen fluoride (HF) gas and one or more ionized particles. The charged particle filter is configured to filter the one or more ionized particles, and the sensing component is configured to detect the HF gas.

A molecular detection apparatus according to an embodiment includes: a collection unit collecting a detection target gas containing a molecule to be detected; a substitution unit substituting a part of a molecular structure of at least a part of the molecule to generate a substitution product; a detector including a plurality of detection cells each having a sensor unit and an organic probe disposed at the sensor unit, the organic probe capturing the molecule or the substitution product; and a discriminator discriminating the molecule by a signal pattern based on an intensity difference of detection signals generated with the molecule or the substitution product being captured by the organic probes of the plurality of detection cells.

Oxy-pyrohydrolysis articles, systems and methods for total halogen, in particular fluorine analysis are provided. A sample containing halogen elements is provided into a pyrotube for combustion. A combustion-enhancing bed including ceramic fibers or fabrics is disposed inside the pyrotube to enhance the combustion and protect the pyrotube from damage by corrosive gases.

Use of a method of identifying the sources of particulates in the atmosphere, including the steps of; quantifying the amount of polycyclic aromatic hydrocarbons and that of nitropolycyclic aromatic hydrocarbons contained in particulates in the atmosphere; and identifying the ratio of combustion-derived particulates in the atmosphere using logical equations derived in advance, which use the amount of polycyclic aromatic hydrocarbons and that of nitropolycyclic aromatic hydrocarbons contained in pre-quantified particulates derived from different combustion sources, and the amount of polycyclic aromatic hydrocarbons and that of nitropolycyclic aromatic hydrocarbons contained in the particulates in the atmosphere obtained in the step of quantifying, allows identification of the sources of particulates in the atmosphere in which mixed particulates from different sources are suspended.