Devices, methods, and systems for trapping multiple ions are described herein. One device includes two or more ovens wherein each oven includes a heating element and a cavity for emitting atoms of a particular atomic species from an atomic source substance, a substrate having a number of apertures that allow atoms emitted from the atomic source substance to exit the oven and enter an ion trapping area and wherein each oven is positioned at a different ion loading area within the ion trapping area, and a plurality of electrodes that can be charged and wherein the charge can be used to selectively control the movement of a particular ion from a particular loading area to a particular ion trap location.

Disclosed herein are embodiments of a system for selectively ionizing samples that may comprise a plurality of different analytes that are not normally detectable using the same ionization technique. The disclosed system comprises a unique split flow tube that can be coupled with a plurality of ionization sources to facilitate using different ionization techniques for the same sample. Also disclosed herein are embodiments of a method for determining the presence of analytes in a sample, wherein the number and type of detectable analytes that can be identified is increased and sensitivity and selectivity are not sacrificed.

A method of analysis using mass spectrometry or ion mobility spectrometry that includes producing ions from a sample in a proximity of the sample, transferring the produced ions from the sample to a distance with a flexible or re-configurable ion guide, the flexible or re-configurable ion guide being connected to RF voltages, and separating the produced ions with a mass to charge or mobility analyzer located at the distance to provide spectrometric results; and detecting the separated ions with at least one detector.

Disclosed is a system for screening of traces of illicit substances that may be harmful, such as explosives, radioactive substances, toxics or drugs for example, from very tiny trace concentrations to be detected by way of mass spectrometry being applied to the detached and pre-concentrated particulate matter by the system. Also disclosed is a method in accordance of the system, an arrangement or device as a system element of the system, and a software code on computer readable medium, to control the system and/or acquire data from the system.

Certain configurations of systems and methods that can detect inorganic ions and organic ions in a sample are described. In some configurations, the system may comprise one, two, three or more mass spectrometer cores. In some instances, the mass spectrometer cores can utilize common components such as gas controllers, processors, power supplies and vacuum pumps. In certain configurations, the systems can be designed to detect both inorganic and organic analytes comprising a mass from about three atomic mass units, four atomic mass units or five atomic mass units up to a mass of about two thousand atomic mass units.

Certain configurations of plasma discharge chambers and plasma ionization sources comprising a plasma discharge chamber are described. In some examples, the discharge chamber comprises a conductive area and is configured to sustain a plasma discharge within the discharge chamber. In other examples, the discharge chamber comprises at least one inlet configured to receive a plasma gas and at least one outlet configured to provide ionized analyte from the discharge chamber. Systems and methods using the discharge chambers are also described.

Method for producing ions for mass spectrometry analysis, including introducing vaporized sample compounds behind a supersonic nozzle and expanding the sample compounds with a carrier gas from the supersonic nozzle into a supersonic nozzle vacuum chamber proximate thereto for vibrationally cooling the sample compounds prior to their ionization. Sample compounds are ionized by either illumination with vacuum ultra-violet photons produced by a continuously operated vacuum ultra-violet photon source or by electrons produced in a fly-through electron ionization ion source; and the ions are transferred to a mass analyzer mounted in a mass analyzer vacuum chamber to obtain mass spectra from vibrationally cold molecules. A quadrupole mass analyzer mounted may be used to obtain mass spectra with dominant molecular ions and fragment ion intensities below 3% of the molecular ion for hydrocarbons. Carrier gas flow rate may exceed 20 ml/min for vibrationally cooling the sample compounds prior to their ionization.

An ion carousel includes a first surface and a second surface adjacent to the first surface. The first and the second surfaces define an ion confinement volume. The second surface including a first inner array of electrodes arranged along a first path and configured to receive, at a first location on the first path, a first ion packet. The first inner array of electrodes are configured to generate a plurality of potential wells that include a first potential well and a second potential well. The first ion packet includes a first sub-packet of ions having a first mobility and a second sub-packet of ions having a second mobility, and the second ion packet includes a third sub-packet of ions having the first mobility and a fourth sub-packet of ions having the second mobility.

An ionizer includes a probe having multiple coaxially aligned conduits. The conduits may carry liquids, and nebulizing and heating gases at various flow rates and temperatures, for generation of ions from a liquid source. An outermost conduit defines an entrainment region that transports and entrains ions in a gas for a defined distance along the length of the conduits. In embodiments, various voltages may be applied to the multiple conduits to aid in ionization and to guide ions. Depending on the voltages applied to the multiple conduits and electrodes, the ionizer can act as an electrospray, APCI, or APPI source. Further, the ionizer may include a source of photons or a source of corona ionization. Formed ions may be provided to a downstream mass analyser.

An ambient or atmospheric pressure ion source is disclosed that comprises a laser source (1) that generates ions and/or neutral particles from a target (2). A transfer device (10) causes the ions and/or neutral particles to pass along a first path or axis within the transfer device (10), while a secondary activation device (6) directs laser radiation or photons along, across or over at least a portion of the first path or axis to cause secondary activation of the ions and/or neutral particles.