The present disclosure relates to an apparatus or methodology for detecting one or more contaminants and/or measuring watering quality in a water supply system, which may be installed at any place chosen by a user so as to detect the one or more contaminants and/or measure the quality of water flowing through a pipe of the water supply system, such as tap water, water purifier, drinking water storage facility, or water intake facility. The present disclosure provides numerous benefits over the existing technology including convenience of handling with ease and safe fastening and installment of the apparatus for detecting one or more contaminants and/or measuring quality of water. Furthermore, the present technology enables the monitoring of the contamination level of the water delivered in the water supply system at any time chosen by the user because the contamination can be detected and/or the water quality can be measured and monitored in a wireless environment either continuously or intermittently through a wireless communication system with a remote user device.

Embodiments of the present invention are directed to methods, systems, and software for assessing contaminant quantities in a fluid. Fluid enters a reaction chamber. A controller then signals two different sheets with different reagents to move into the reaction chamber. One sheet contains reagents to form a contaminant byproduct or gas, while the other sheet is saturated with reagent that will have a photometric effect upon reacting with the contaminant byproduct or gas. After the photometric effect has occurred, the controller moves the reacted portion of the other reagent sheet into alignment with a photometric sensor. This photometric effect is calculated to contaminant concentration. The concentration is recorded and the data is transmitted to memory. The fluid sample in the chamber is drained and the remaining solid waste is collected onto the first reagent sheet. Both sheets are individually collected into separate controllable collectors.

The invention relates to a sensor assembly to detect and quantify organic and/or inorganic mercury compounds, including elemental mercury that may be present in gases or liquids, such as natural gas, air, condensates, crude oil, refined petroleum gas or liquids, and water including connate water, condensed water and water containing hydrate inhibitor(s). The sensor assembly includes a housing having a flow channel defined by an inlet, a sensor array, and an outlet. The sensor array is based on the differential sorption properties measured using a surface acoustic wave (SAW) sensor array, a chemiresistor array, or a combination of the two.

Certain embodiments include a sensor system for measuring chlorine concentration in water. The sensor system can have a manifold including one or more flow passages for receiving fluid flow. The sensor system can have a probe for measuring chlorine concentration in fluid communication with a flow passage of the one or more flow passages of the manifold. The probe can have a probe body oriented to direct incoming fluid from one or more flow passages of the manifold toward an end of the probe body. The probe can have a plurality of flutes defined on an outer surface of the probe body. The flutes can be shaped and oriented to direct fluid from the end proximal to the electrodes, back toward the one or more flow passages of the manifold.

The present invention relates to a process for the detection and adsorption of arsenic from ground water and industrial waste water using lanthanide doped nanoparticles. More particularly, the present invention provides a process for the detection and adsorption arsenic in ppm level using Eu.sub.0.05Y.sub.0.95PO.sub.4 nanoparticles.

A novel substrate-bound DNAzyme complex is provided comprising a DNAzyme bound to a nucleic acid-based substrate. The DNAzyme comprises a pair of binding arms which hybridize to binding regions on the substrate, and a catalytic domain between the binding arms. The nucleic acid-based substrate comprises a phosphorothioate-modified ribonucleotide cleavage site between the binding regions of the substrate. The catalytic domain of the DNAzyme catalyzes heavy metal-dependent cleavage of the substrate cleavage site. The DNAzyme complex is useful in a method of heavy metal sensing. A novel cadmium-selective DNAzyme is also described for cadmium sensing.

According to one embodiment of the present invention, an azo polymer forms a complex with a lithium ion and a sodium ion among alkali metal ions, but does not form a complex with a potassium ion. Therefore, the azo polymer is expected to be utilized as a material for a sensor capable of selectively detecting a specific alkali metal ion, or as a novel material capable of selectively trapping a specific alkali metal ion from a solution in which metal ions are mixed.

A method of removing and detecting the presence of substances from at least one of a body of water and the air. The method includes placing into the body of water or into the air an open-cell foam material, removing separate portions of the open-cell foam material from the water or air at different exposure times after the open-cell foam material was placed into the water or air, and determining the presence in the removed separate portions of one or more substances that were removed from the water or air by the open-cell foam material.

A method may comprise: exposing a substituted chromone dissolved in a solvent to a sample; taking a fluorescence measurement of the sample after exposure to the substituted chromone; and determining a presence or absence of one or more ions in the sample, a concentration of the one or more ions in the sample, or both based on the fluorescence measurement.

A method of detecting one or more heavy metals in a sample solution is provided. The disclosure includes adding a dye to the sample solution having the one or more heavy metals to produce a color mixture. Mesoporous TiO.sub.2 NPs are added to the color mixture to preconcentrate metal-dye complex onto the surface of the mesoporous TiO.sub.2 NPs. Presence of the one or more heavy metals is detected by change in color within about 30 seconds via a naked eye. The disclosure further includes a method of determining concentration of one or more heavy metals in a sample solution by absorbance.