An apparatus for individually trapping atoms, individually imaging the atoms, and individually cooling the atoms to prevent loss of the atoms from the trap caused by the imaging. The apparatus can be implemented in various quantum computing, sensing, and metrology applications (e.g., in an atomic clock).

The invention provides a method and device for measuring mercury isotopes in natural gas. The method includes the following steps: (1) primary enrichment: subjecting natural gas to a three-stage cascading absorption with an acidic potassium permanganate aqueous solution, and collecting all of the acidic potassium permanganate aqueous solutions in which natural gas is absorbed in step (1); (2) mercury purification and enrichment: reducing the mercury absorbed in the step (1) to mercury vapor with a stannous chloride solution, and then purifying and enriching the mercury vapor by using an acidic potassium permanganate aqueous solution; (3) detecting the acidic potassium permanganate solution in which the mercury vapor is enriched in step (2) to determine the total mercury content therein; and (4) detecting the acidic potassium permanganate solution in which the mercury vapor is enriched in step (2) to determine the composition/content of stable mercury isotopes therein.

The present disclosure relates to a method and device for detecting mercury isotopes in crude oil. The device comprises an enrichment-absorption system and a secondary purification-enrichment system for mercury isotopes, wherein the enrichment-absorption system includes an air-background mercury absorption system, a pyrolysis/cracking system, a mercury-sample absorption system connected in series with pipe lines, and a vacuum pump, and the vacuum pump is connected to the mercury-sample absorption system through a pipe line; the secondary purification-enrichment system includes a nitrogen-gas cylinder, a collection bottle with potassium permanganate absorption liquid, and a secondary enrichment-absorption bottle connected in series with pipe lines, wherein the secondary purification-enrichment system further includes a stannous-chloride storage bottle, which is connected to a pipe line between the nitrogen-gas cylinder and the collection bottle with potassium-permanganate absorption liquid via a peristaltic pump and through a pipe line.

The invention relates to a method and a device for detecting mercury isotopes in an oil-gas source. The device includes at least one enrichment-absorption system for mercury in crude oil/hydrocarbon source rock, an enrichment-absorption system for mercury in natural gas and at least one secondary purification-enrichment system for mercury; the enrichment-absorption system for mercury in crude oil/hydrocarbon source rock comprises three air-absorption bottles, a pyrolysis/cracking system, five impact samplers, and a vacuum pump, which are connected in series by pipe lines; and the enrichment-absorption system for mercury in natural gas includes five impact samplers connected in series, wherein the first impact sampler is connected to the natural gas outlet from the natural gas well and the last impact sampler is connected to the cumulative gas flow meter.

An apparatus for individually trapping atoms, individually imaging the atoms, and individually cooling the atoms to prevent loss of the atoms from the trap caused by the imaging. The apparatus can be implemented in various quantum computing, sensing, and metrology applications (e.g., in an atomic clock).

Non-invasive and minimally-invasive detection of serum iron in real time. In a method for detecting serum iron content disclosed herein, the method includes positioning a device relative to a nonpigmented epithelial layer covering capillaries of a mammalian subject, operating the device to obtain optical data relating to the capillaries, and determining serum iron content of blood within the capillaries based upon the optical data.

A spectrometer and a fabrication method thereof. The spectrometer includes: a first base substrate; a second base substrate opposite to the first base substrate; a detection channel between the first base substrate and the second base substrate; a quantum dot light emitting layer on a side of the first base substrate that is close to the second base substrate, and including a plurality of quantum dot light emitting units; a black matrix on the side of the first base substrate that is close to the second base substrate, and configured to separate the plurality of quantum dot light emitting units; and a sensor layer, including a plurality of sensors, the plurality of sensors being in one-to-one correspondence with the plurality of quantum dot light emitting units.

A gas analyzer may include: a gas chamber configured to receive a gas to be analyzed therein, a radiation source configured to emit electromagnetic radiation into the gas chamber, the electromagnetic radiation being adapted to selectively excite gas molecules of a specific type that is to be detected in the gas received in the gas chamber, a collimator configured to collimate the electromagnetic radiation emitted by the radiation source, and a sensor configured to detect a physical quantity indicative of a degree of interaction between the electromagnetic radiation emitted by the radiation source and the gas to be analyzed.

The invention relates to a portable multi-spectrometry system for chemical and biological sensing in atmospheric air. A portable, spectrometric system integrates multiple spectroscopy theories, combines their advantageous features, and fills the gaps for their limitations. The combined spectrometry system with operations for PLS, IRAS, MAS, MFS, RSS, and MS, will detect particles and chemicals, directly and sequentially, in the same air-stream.

A method for inspecting an article containing a target material is provided. A sampling position of the article is illuminated by a beam of laser light having a wavelength . Illumination focus to a focal point at the sampling position of the article to produce molecular excitation of the target material by simultaneous absorption of n incident photons of the beam of laser light, wherein n is equal to or greater than two. An output light exited from the article is analyzed by a detector, wherein the output light is of a wavelength range between 0.8 and 1.2.