Systems and methods are described for automatically utilizing multiple data processing methods on a given spectrometry dataset for the determination of nanoparticle detection factors including nanoparticle baseline and detection threshold.

An ion guide may comprise a set of plate electrodes, each plate electrode having a plurality of apertures formed therethrough. The set of plate electrodes are spatially arranged such that a relative positioning of each plurality of apertures of a respective plate electrode of the set of plate electrodes and respective adjacent plate electrodes of the set of plate electrodes defines a continuous ion flight path through the respective plurality of apertures of each plate electrode of the set of plate electrodes. The continuous ion flight path has a helical-based and/or spiral-based shape.

An ion guide may comprise a set of plate electrodes, each plate electrode having a plurality of apertures formed therethrough. The set of plate electrodes are spatially arranged such that a relative positioning of each plurality of apertures of a respective plate electrode of the set of plate electrodes and respective adjacent plate electrodes of the set of plate electrodes defines a continuous ion flight path through the respective plurality of apertures of each plate electrode of the set of plate electrodes. The continuous ion flight path has a helical-based and/or spiral-based shape.

A device (1) for manipulating charged particles, the device comprising a series of electrodes (2, 3) disposed so as to form a channel for transportation of the charged particles. A power supply unit (5) provides a first supply voltage (7) which changes according to a waveform having a period (T), to axially segmented bunching electrodes (3) to create an electric field within the channel. The potential of the electric field defines a potential well which is translated along the length of the channel such that the potential well is translated a distance substantially equal to its length in an interval of time substantially equal to the period (T). The waveform is substantially continuously smooth throughout its period (T); and, substantially constant in value throughout a finite duration of time (T.sub.L<T) within the period (T), corresponding to a minimum of the waveform. A power supply unit (6) provides a second supply voltage (8) to radial confinement electrodes (2) to create a radially confining electric field within the channel configured to radially confine charged particles within the channel.

A device (1) for manipulating charged particles, the device comprising a series of electrodes (2, 3) disposed so as to form a channel for transportation of the charged particles. A power supply unit (5) provides a first supply voltage (7) which changes according to a waveform having a period (T), to axially segmented bunching electrodes (3) to create an electric field within the channel. The potential of the electric field defines a potential well which is translated along the length of the channel such that the potential well is translated a distance substantially equal to its length in an interval of time substantially equal to the period (T). The waveform is substantially continuously smooth throughout its period (T); and, substantially constant in value throughout a finite duration of time (T.sub.L<T) within the period (T), corresponding to a minimum of the waveform. A power supply unit (6) provides a second supply voltage (8) to radial confinement electrodes (2) to create a radially confining electric field within the channel configured to radially confine charged particles within the channel.

An ion guide may comprise a set of plate electrodes, each plate electrode having a plurality of apertures formed therethrough. The set of plate electrodes are spatially arranged such that a relative positioning of each plurality of apertures of a respective plate electrode of the set of plate electrodes and respective adjacent plate electrodes of the set of plate electrodes defines a continuous ion flight path through the respective plurality of apertures of each plate electrode of the set of plate electrodes. The continuous ion flight path has a helical-based and/or spiral-based shape.

An ion guide may comprise a set of plate electrodes, each plate electrode having a plurality of apertures formed therethrough. The set of plate electrodes are spatially arranged such that a relative positioning of each plurality of apertures of a respective plate electrode of the set of plate electrodes and respective adjacent plate electrodes of the set of plate electrodes defines a continuous ion flight path through the respective plurality of apertures of each plate electrode of the set of plate electrodes. The continuous ion flight path has a helical-based and/or spiral-based shape.

A mass spectrometer includes: a multi-pole ion guide including a first electrode pair and a second electrode pair arranged symmetrically with respect to the central axis; a first transmission portion connected to the first electrode pair and transmits an RF voltage to be applied to the first electrode pair; and a second transmission portion connected to the second electrode pair and transmits an RF voltage to be applied to the second electrode pair, wherein: the first transmission portion includes a capacitor that reduces the difference between the capacitance of the first transmission portion and the capacitance of the second transmission portion.

A mass spectrometer includes: a multi-pole ion guide including a first electrode pair and a second electrode pair arranged symmetrically with respect to the central axis; a first transmission portion connected to the first electrode pair and transmits an RF voltage to be applied to the first electrode pair; and a second transmission portion connected to the second electrode pair and transmits an RF voltage to be applied to the second electrode pair, wherein: the first transmission portion includes a capacitor that reduces the difference between the capacitance of the first transmission portion and the capacitance of the second transmission portion.

The efficiency and accuracy of search for a compound exhibiting a distribution similar to that of a reference image such as an optical microscope image are improved in imaging mass spectrometric analysis. In an imaging mass spectrometer including a data processing device according to the present invention, a regression analysis executor (16) executes PLS using mass spectrum data and reference image data for each measurement point and calculates a regression coefficient reflecting the similarity of the distribution for each m/z value. An m/z value search section (17) selects m/z values in descending order of regression coefficients, but in each search m/z range obtained by dividing the entire measurement m/z range for each predetermined width, excludes a search m/z range including one m/z value already selected from the search target. Since the peak originating from a certain compound and its isotope peak fall within almost one search m/z range on the mass spectrum, the process described above can avoid selection of the m/z value of ions originating from a certain compound and the m/z value of ions originating from its isotope in duplicate as an m/z candidate.