The sample support is used for ionization of a sample contained in a sample solution dropped using a pipette tip. The sample support includes a substrate formed with a plurality of through holes opened in a first surface and a second surface, and a frame that is formed with a through hole penetrating in a thickness direction of the substrate so as to overlap a measurement region when viewed from the thickness direction and that is bonded to the first surface of the substrate. The through hole of the frame includes a narrow portion having a width smaller than the outer diameter of a tip of the pipette tip.

The present invention relates to a composition analysis technology of ultramicro-volume liquid by laser ablation plasma mass spectrometry. Using a pipette gun to extract the liquid to be detected in a low-temperature environment, dropping the liquid into a dropping pit in a dropping plate, the liquid level is slightly higher than an overflow table in the dropping plate; dropping different liquid samples into different dropping pits by the same method; gradually covering the dropping pit with an analysis film having an area 1.5 times larger than that of the dropping plate from one side of the dropping plate, tightly adhering the thin film onto the dropping plate by using a transparent adhesive tape, the thin film is in close contact with the liquid level; placing the dropping plate covered by the thin film in a LA-ICPMS universal solid sample chamber, and then setting parameters for ablation.

One mode is a method for the structural analysis of an organic compound by MALDI mass spectrometry, including: a sample preparation process (S1) which includes preparing a sample by mixing a specimen containing an organic compound to be analyzed with a predetermined matrix at a mixture ratio within a range from 1:5 to 1:5000 in molar ratio; a mass spectrometry process (S3) which includes irradiating the prepared sample with a laser beam having a spot size equal to or smaller than 15 μm to generate ions originating from a component of the specimen in the sample, and performing a mass spectrometric analysis of the generated ions; and an analyzing process (S4) which includes detecting, from a mass spectrum acquired in the mass spectrometry process, ions including product ions resulting from in-source decay, and estimating the structure of the organic compound to be analyzed based on information concerning the ions.

Disclosed are systems and methods to provide rapid and autonomous detection of analyte particles in gas and liquid samples. Disclosed are methods and devices for identifying biological aerosol analytes using MALDI-MS and chemical aerosol analytes using LDI and MALDI-MS using time-of-flight mass spectrometry (TOFMS).

A method for detecting and analyzing olefins in petroleum by electrospray ionization mass spectrometry can include obtaining a hydrocarbon sample comprising at least about 90 wt % of saturate compounds; producing a solution comprising the hydrocarbon sample and a metal salt, the metal salt comprising a metal ion; forming olefin-metal ion complexes by electrospray ionization; and detecting the olefin-metal ion complexes using mass spectrometry.

Provided is a sample support body that includes: a substrate having a first surface and a second surface opposite to each other; and a conductive layer provided on at least the first surface. A plurality of through-holes, which open to the second surface and a third surface of the conductive layer which is located on a side opposite to the substrate, are formed in the substrate and the conductive layer. At least one of the second surface and the third surface is subjected to surface treatment for providing a difference in an affinity with water between a surface close to the second surface and a surface close to the third surface.

A sample support is a sample support for sample ionization, including: a substrate formed with a plurality of through holes opening to a first surface and a second surface on a side opposite to the first surface; a conductive layer provided not to block the through hole in the first surface; and a frame body provided in a peripheral portion of the substrate to surround an ionization region in which a sample is ionized when viewed in a thickness direction of the substrate, in which a marker for recognizing a position in the ionization region is provided in the frame body.

A method for measuring the chirality of molecules in a sample of chiral molecules, the sample including at least one chemical species, the method including the steps of: introducing the sample of chiral molecules into an ionisation area; ionising the molecules by electromagnetic radiation in the ionisation area; and detecting a distribution of electrons produced by ionisation and emitted at the front and back of the ionisation area relative to the axis, z, of propagation of the electromagnetic radiation; wherein the electromagnetic radiation is elliptically polarised, the ellipticity varying continuously and periodically as a function of time, the method further including a step of: determining the chirality of the molecules from the electron distribution detected continuously as a function of time. A system is also provided for measuring the chirality of molecules using such a method.

Disclosed are systems are methods for identifying the composition of single aerosol particles, particularly that of bioaerosol particles, without pre-treatment using complex organic MALDI matrices. A continuous timing laser may be used to index aerosol particles, measure particle properties, and trigger a pulse ionization laser. Ionized fragments and optionally photons associated with each particle producing by the ionization laser may be analyzed using one or more detectors including a TOF-MS detector and an optical detector. The laser pulse may comprise a simultaneous IR and UV laser pulse when fragments comprise predominantly of UV chromophores. Unique spectral data associated with each indexed particle from each detector may be compiled using data fusion to generate compiled spectral data. Machine learning methods may be used to improve the prediction of composition over time.

Disclosed are systems are methods for identifying the composition of single aerosol particles, particularly that of bioaerosol particles. A continuous timing laser tightly coupled with a pulse ionization laser is used to index aerosol particles, measure particle properties, and trigger the ionization laser to fire when each particle enters the beam of the trigger laser. Ionized fragments and optionally photons produced when each particle is struck by the ionization laser are analyzed using one or more detectors including a TOF-MS detector and an optical detector. Individual single particle spectra are aligned and denoised prior to averaging.