Certain configurations of devices and systems which are configured to draw a selected volume of an air sample into a trap are described. In some examples, the devices and systems comprise a pump and a mass flow sensor to draw a selected volume of the air sample through a trap even where variable restriction occurs.

An embodiment of a method for real time material identification is described that comprises determining an approximate mass value for an unknown material from spectral information derived from mass spectral analysis of the unknown material; retrieving profile models that correspond to a known material from a data structure using the approximate mass value; fitting a sample profile for the unknown material from the spectral information to the profile models to generate a fit score for each fit, wherein the lowest fit score corresponds to the best fit; calculating a mass value from the best fitting profile model and the sample profile.

An embodiment of a method for real time material identification is described that comprises determining an approximate mass value for an unknown material from spectral information derived from mass spectral analysis of the unknown material; retrieving profile models that correspond to a known material from a data structure using the approximate mass value; fitting a sample profile for the unknown material from the spectral information to the profile models to generate a fit score for each fit, wherein the lowest fit score corresponds to the best fit; calculating a mass value from the best fitting profile model and the sample profile.

In mass spectrometry, ion optics process a received ion beam into an output ion beam travelling in an output direction and having a spatial distribution in a plane perpendicular to the output direction elongated in one dimension of the plane relative to the other dimension of the plane and defines an axis of elongation thereby. A quadrupole ion optical device comprises first and second pairs of opposing elongated electrodes, receiving the output ion beam travelling along the output direction and defining an acceptance axis in a plane perpendicular to the direction of elongation of the first and second pairs of opposing elongated electrodes. The acceptance axis is an axis on which maximum acceptance of ions to the quadrupole ion optical device is attained. The first and second pairs of opposing elongated electrodes are oriented substantially to match the acceptance axis to the axis of elongation defined by the spatial distribution.

A sample preparation apparatus for an elemental analysis system comprising a sample combustion and/or reduction and/or pyrolysis arrangement for receiving a sample of material to be analysed, and producing therefrom a sample gas flow containing atoms, molecules and/or compounds; a gas chromatography (GC) column into which the sample gas flow is directed; a heater for heating at least a part of the GC column; and a controller for controlling the heater. The controller is configured to control the heater so as to increase the temperature of at least the part of the GC column whilst the sample gas flow in the GC column elutes.

Apparatuses, systems, and methods for ion traps are described herein. One apparatus includes a number of microwave (MW) rails and a number of radio frequency (RF) rails formed with substantially parallel longitudinal axes and with substantially coplanar upper surfaces. The apparatus includes two sequences of direct current (DC) electrodes with each sequence formed to extend substantially parallel to the substantially parallel longitudinal axes of the MW rails and the RF rails. The apparatus further includes a number of through-silicon vias (TSVs) formed through a substrate of the ion trap and a trench capacitor formed in the substrate around at least one TSV.

A sub-ambient gas pressure ion separation device is disclosed comprising: an ion entrance aperture having an axis therethrough that extends in a first direction, and an ion exit aperture; wherein the entrance aperture and exit aperture are spatially separated from each other in the first direction and in a second, orthogonal direction; and means for urging ions in said second direction as the ions travel in the first direction, said means for causing ions to separate in said second direction according to a physicochemical property such that ions having a first value, or first range of values, of the physicochemical property exit the device through the exit aperture and other ions having a different value, or different range of values, of said physicochemical property do not exit the device through the exit aperture.

Apparatuses, systems, and methods for performing mass analysis are disclosed. One such apparatus may include an ion trap device for use in a mass analysis system. The ion trap device may comprise an ion trap and a signal generator for applying an excitation signal to the ion trap. The signal generator may include a plurality of oscillators each configured to selectively generate a corresponding sinusoid signal to be selectively combined to form the excitation signal.

Ions ejected substantially simultaneously from a collision cell after being temporarily held inside the collision cell arrive at an orthogonal acceleration unit through an ion transport optical system. When the ions enter the orthogonal acceleration unit, voltages having a predetermined potential difference are applied to an entrance-side electrode and an exit-side auxiliary electrode, and as a result an electric field having a rising potential gradient along an axis is created in the orthogonal acceleration unit. As ions having low an m/z values and entering the orthogonal acceleration unit first is significantly decelerate, the packet of ions spread in the X-axis direction in accordance with the m/z values are compressed in the X-axis direction after entering the orthogonal acceleration unit. Thus, a mass-to-charge ratio range of ions that are accelerated in the orthogonal acceleration unit is broadened, and a mass spectrum of a broad range of mass-to-charge ratios can be obtained.

A method for identifying a reagent during a process in an analysis system is disclosed. The analysis system comprises a liquid chromatograph and a mass spectrometer. The method comprises providing a reagent, adding at least one chemical substance to the reagent with a concentration being below a detection level of the mass spectrometer, enriching the chemical substance within the liquid chromatograph to a concentration above the detection level of the mass spectrometer, processing the reagent together with the enriched chemical substance by means of the analysis system, and identifying the reagent based on a detection of a substance detection signal of the mass spectrometer representing the chemical substance.