The invention discloses an atomic fluorescence analysis method and device using water as a carrier fluid, belonging to the atomic fluorescence analysis in the field of analytical chemistry; the method is to replace hydrochloric acid and a reducing agent with water as the carrier fluid in the conventional sampling and fluid delivery process to carry the test liquid and reagent into the reactor to complete a reaction. The invention effectively overcomes the memory effect by using water as the carrier fluid and improves the determination sensitivity and accuracy, which saves a large amount of high-purity hydrochloric acid and reducing agent at the same time, greatly reducing the analysis cost, and significantly improving the operating environment, which is the innovation of atomic fluorescence analysis technology.

Optical spectroscopy system and method possessing spectral selectivity sufficient to distinguish isotopic line of the metal of interest. Each of the light beams, counter-propagating through vial with vapor of the sample, has been originated from the same light output of the laser source and modulated at a corresponding judiciously-determined frequency. The light-output, in turn, possesses a carrier frequency and two side-band frequencies defined with respect to a mean value of excitation frequencies of isotopes in the vapor.

A detector apparatus is provided and includes a collector having access to a sample of a gaseous fluid and a tester coupled to and disposed remotely from the collector. The tester includes a test chamber into which a sample is directed from the collector, an excitation element to excite the sample in the test chamber and a spectrum analyzing device coupled to the test chamber to analyze the excited sample for evidence of a concentration of particles of interest in the gaseous fluid exceeding a threshold concentration. The threshold concentration is defined in accordance with a type of the particles of interest and a residence time of the sample.

A system and method for detecting and quantifying the concentration of rare earth elements in a fluid contacting a sensor, the method having the steps of: providing the sensor to an environment such that the sensor is in contact with the fluid, wherein the sensor features a fiber extending between a first end and a second end along a longitudinal axis, wherein the sensor further features a coating on the second end of the fiber, and wherein the coating is a metal-organic framework material including, but not limited to zinc adeninate, 1,3,5-benzenetricarboxylate, 4,4-biphenyldicarboxylate, and combinations thereof; interrogating the sensor with light; collecting a luminescent signal; and detecting the rare earth elements in the fluid contacting the sensor using the luminescent signal.

Optical spectroscopy system and method possessing spectral selectivity sufficient to distinguish isotopic line of the metal of interest. Each of the light beams, counter-propagating through vial with vapor of the sample, has been originated from the same light output of the laser source and modulated at a corresponding judiciously-determined frequency. The light-output, in turn, possesses a carrier frequency and two side-band frequencies defined with respect to a mean value of excitation frequencies of isotopes in the vapor.

A controller of an atomic system controls operation of potential sources to cause potential generating signals to be provided. Application of the potential generating signals to respective potential generating elements causes performance of a split operation causing confinement of a first subset of atomic objects of an object crystal in a first potential well and a second subset of atomic objects of the object crystal in a second potential well. The first subset consists of one or more atomic objects. The object crystal includes atomic objects of at least two species. The controller controls operation of manipulation sources to cause manipulation signals to be incident on the first subset. The controller receives a sensor signal generated by a photodetector configured to capture fluorescence signals generated by the first subset. The controller processes the sensor signal to determine a respective species of at least one atomic object of the first subset.

A system and method for detecting and quantifying the concentration of rare earth elements in a fluid contacting a sensor, the method having the steps of: providing the sensor to an environment such that the sensor is in contact with the fluid, wherein the sensor features a fiber extending between a first end and a second end along a longitudinal axis, wherein the sensor further features a coating on the second end of the fiber, and wherein the coating is a metal-organic framework material including, but not limited to zinc adeninate, 1,3,5-benzenetricarboxylate, 4,4-biphenyldicarboxylate, and combinations thereof; interrogating the sensor with light; collecting a luminescent signal; and detecting the rare earth elements in the fluid contacting the sensor using the luminescent signal.