A passive sampler deployment housing, the housing comprising a channel for guiding a stream flow of a liquid in a main direction, the channel having two side walls and one downstream wall, defining a sampling chamber; at least one support means adapted for supporting at least one detecting means and arranged in the channel, the downstream wall, disposed essentially perpendicular to the liquid main direction, having a height such that the flow of the liquid is accumulated in the channel at a level that is sufficient to overlap the support means and optionally the detecting means. The invention also relates to a device including the housing of and at least one detecting means, the at least one detecting means comprising a frame including two membrane supporting means, and a membrane, comprising a sorbing material, which is clamped therebetween.

A sample may be prepared and then analyzed using a liquid chromatography with tandem mass spectrometry system to determine presence and concentration of herbicide(s) present in the sample. In some examples, the method involves providing a sample containing one or more herbicides and adding a base to the sample. The base may increase the pH of the sample to ≥12, thereby hydrolyzing esters of the one or more herbicides. The method may further involve, subsequent to hydrolyzing the esters of the one or more herbicides, adding an acid to the sample so as to lower the pH of the sample to ≤3. Once prepared, the sample can be injected into a liquid chromatography instrument to separate the herbicide molecules from other molecules present in the sample before being ionized and characterized by mass-to-charge ratio and relative abundance using one or more mass spectrometers.

An open-cell foam structure that is used to detect and remove substances from water or air.

An analytical system and method for periodically monitoring an injection water distribution pipeline for the presence and concentration of formaldehyde or other aldehyde-functional biocide includes pumps, one of which provides a predetermined volume of injection water drawn from the pipeline at a sampling point and the other a predetermined volume of a reagent, preferably a buffered solution of dimedone, from a reagent storage vessel which are mixed and then heated in a chamber to a predetermined temperature to promote formation of any reaction products. The heated reaction mixture is passed to a detection cell and exposed to light of predetermined wavelength which, in accordance with the Hantzsch reaction, molecules having an aldehyde functional group that reacted with dimedone produce a fluorescence-emitting reaction product, the intensity of which is measured and compared to data previously obtained from standard aldehyde-containing solutions.

The present application discloses methods for detecting and quantifying tetrakis(hydroxymethyl) phosphonium sulfate (THPS) in a water sample. In the methods, a water sample is mixed with a KMnO.sub.4 solution to form a mixture. An intensity of KMnO.sub.4 absorption in the mixture is then measured at a wavelength of 525 nm. The measured intensity is normalized by subtracting a background intensity at a wavelength of 650 nm. The presence and concentration of THPS in the water sample can then be determined by comparing the normalized intensity with intensity values of KMnO.sub.4 absorption of calibration samples comprising KMnO.sub.4 and known THPS concentrations.

A method for detecting glutaraldehyde in a water sample in which Au-BSA nanoclusters have been introduced is provided. In the method, the water sample is mixed with the Au-BSA nanoclusters to form a mixture. The mixture is incubated for 2 to 10 minutes, and the glutaraldehyde present in the mixture reacts with the Au-BSA nanoclusters and causes fluorescence quenching of the Au-BSA nanoclusters. Then a fluorescence intensity of the quenched Au-BSA nanoclusters in the mixture is measured at an emission wavelength of 675 nm. A presence and concentration of glutaraldehyde in the water sample is then determined by comparing the measured fluorescence intensity of the quenched Au-BSA nanoclusters at the emission wavelength of 675 nm with fluorescence intensity values of calibration samples comprising Au-BSA nanoclusters and known glutaraldehyde concentrations.

Various aspects of the present disclosure are directed to methods and systems for in-situ accumulation of one or more substances from a liquid environment. In one embodiment of the present disclosure, a method is disclosed including placing a cartridge with a sorbent in the liquid environment, driving a liquid volume through the sorbent, and repeating the act of driving as a function of time.

This disclosure provides quantitative, rapid, and reliable LC-MS/MS methods for analyzing panels of pesticides and mycotoxins in various samples, including very hydrophobic and chlorinated compounds normally analyzed on a GC-MS/MS system. The methods can be carried out using a single instrument and can detect and quantify levels of the pesticides and mycotoxins that are well below action limits specified by U.S. states (e.g., California) and other countries (e.g., Canada) for these compounds in cannabis products.

A system for real-time spectrographic analysis for automatically identifying contaminants in water comprising: a spectrometer configured to process electromagnetic radiation emitted by a plasma created between a solid electrode and a liquid electrode; and a control node operatively connected to the spectrometer, the control node comprising a processor and a memory on which are stored machine-readable instructions that when executed by the processor, cause the processor to acquire spectroscopic data from the spectrometer and to analyze the spectroscopic data to determine concentration levels of contaminants in the water sample.

A water quality and flow monitoring and control apparatus, method and system installed at an end user location and being capable of monitoring one or more of the following water quality parameters: microorganisms (including E. coli), mineral or other ion concentration, pH, temperature, and turbidity. The system also has a water meter that detects the flow of water and has a valve to shut the flow of water off upon detecting a fault condition such as a leak.