Disclosed herein are methods and systems for capture and measurement of a target component. A fluid sampling tool for sampling fluid from a subterranean formation may include a sample chamber having a fluid inlet, wherein the sample chamber is lined with a coating of a material that can reversibly hold a target component.

Provided is a method of producing a metal nanoparticle-oxide support complex structure, in which metal nanoparticles uniform in size are evenly distributed on the surface of oxide supports. A gas sensor with improved gas sensing ability and durability may be provided by using the same.

A sensor assembly having a housing including a plurality of compartments, an actuator for selectively hermetically sealing or fluidly connecting the plurality of compartments, a plurality of sensors each positioned in a corresponding compartment, and a receiver is disclosed. A method of monitoring a parameter of a fluid in a remote location is also disclosed. The method includes deploying the sensor assembly to the remote location, fluidly connecting a first sensor to the fluid, transmitting to an external controller data including values for the measured parameter of the fluid, and operating the actuator to fluidly connect a second sensor responsive to the operating interval of the first sensor trending to expiration. A sensing system having a sensor assembly and an external controller is also disclosed. A method of facilitating monitoring a parameter of the fluid in a remote location by providing the sensor assembly is also disclosed.

The present invention relates to systems and methods for automated monitoring of an environment enclosed by a manhole cover having a manhole. The automated monitoring of the environment generally includes obtaining a first reading from a first sensor coupled to a monitoring assembly, transferring the first reading from the first sensor to an Information Processor and Cloud Transceiver (IPCT), processing the first reading from the first sensor in the IPCT to create an output defined as an operating condition of the environment and communicating the operating condition of the environment across a communications network and to a server when the reading is flagged. The monitoring assembly is attached to either an in-flow protector dish or a ring with support brackets, to allow easy installation and removal without concern for the weight of a manhole cover.

The invention relates to a method for in-situ measurement of the concentration of gaseous chemical species contained in a biogas (10) flowing in a pipe (20), for example in a biogas treatment plant or a system using biogas.

The method according to the invention is implemented by means of an optical measurement system (40) including a light source (41) and a spectrometer (44). Source (41) emits a UV radiation (42) through the biogas (10) within a measurement zone (21) in the pipe. Spectrometer (44) detects at least part of said UV radiation that has passed through biogas (10) and it generates a digital signal of the light intensity (50) as a function of the wavelength of the part of the UV radiation that has passed through the biogas. The chemical species concentration is then determined from digital light intensity signal (50).

A method for identifying a sample includes collecting a sample in a sample cylinder, directing the sample from the sample cylinder to a tube with controlled pressure, and identifying a phase, a color, and existence of impurities of the sample through a transparent portion of the tube.

An H.sub.2S sensor includes at least one acoustic wave transducer and a film having a polymer matrix. The polymer matrix includes carboxylate functional groups and lead or zinc cations. The film may have a thickness of between a hundred nanometres and a 2 microns The H.sub.2S sensor optionally includes an antenna to remotely interrogate the H.sub.2S sensor.

A method for detecting for the presence of H.sub.2S or HS.sup.− anion in a system, comprising contacting a sample from the system with a compound, or a protonate or salt thereof, having a structure represented by: ##STR00001## wherein Y represents an aromatic group or a substituted aromatic group; n is 1 or 2; R is independently H, alkyl, substituted alkyl, a polyether moiety, carboxyl, substituted carboxyl, carbamate, substituted carbonate, carbonyloxy, alkoxy, substituted alkoxy, haloalkyl, halogen, nitro, amino, amido, aryloxy, cyano, hydroxyl, or sulfonyl; R.sup.1 is H, substituted lower alkyl, lower alkyl, substituted aralkyl or aralkyl; R.sup.2 is selected from H, acyl, substituted aralkyl, aralkyl, phosphonyl, —SO.sub.2R.sup.3; —C(O)R.sup.5; —C(O)OR.sup.7 or —C(O)NR.sup.9R.sup.10; R.sup.3; R.sup.5; R.sup.7; R.sup.9 and R.sup.10 are each independently selected from H, substituted lower alkyl, lower alkyl, substituted aralkyl, aralkyl, substituted aryl or aryl.

A member for a metal oxide nanofiber based gas sensor can include a metal nanoparticle catalyst and can be formed to be functionalized by binding the metal nanoparticle catalyst and an alkali or alkaline earth metal through electrospinning and heat treatment processes. The member can detect a trace amount of a gas with high selectivity and ultra-high sensitivity by uniformly binding the alkali or alkaline earth metal and the metal nanoparticle catalyst through electrospinning and high-temperature heat treatment.

A gas analysis system with an FTIR spectrometer preferably utilizes a long path gas cell, a narrow band detector, and an optical filter that narrows the detection region to measure hydrogen sulfide.