A mass spectrometer is provided having an ion source for generating ions from a sample in a high pressure region, a first vacuum chamber having an inlet aperture, and an exit aperture. The at least one ion guide can be between the inlet and exit apertures and can include an entrance end and an exit end. The at least one ion guide can have a plurality of electrodes arranged around a central axis defining an ion channel, each of the plurality of electrodes being tapered, a planar surface of each of the plurality of tapered electrodes facing the interior of the at least one ion guide, and the surface gradually being narrowed and tilted inward to provide a smaller inscribed radius at the exit; and a power supply for providing an RF voltage to the at least one ion guide.

A method of operating a quadrupole device is disclosed that comprises operating the quadrupole device in a first mode of operation, and operating the quadrupole device in a second mode of operation. Operating the quadrupole device in the first mode of operation comprises applying one or more first voltages to the quadrupole device such that the quadrupole device is operated in an initial stability region and such that at least some ions are stable within the quadrupole device. Operating the quadrupole device in the second mode of operation comprises applying one or more second voltages to the quadrupole device such that the quadrupole device is operated in a different stability region and such that at least some of the ions that were stable within the quadrupole device in the first mode of operation are stable within the quadrupole device in the second mode of operation.

A space-time buffer includes a plurality of discrete trapping regions and a controller. The plurality of discrete trapping regions is configured to trap ions as individual trapping regions or as combinations of trapping regions. The controller is configured to combine at least a portion of the plurality of trapping regions into a larger trap region; fill the larger trap region with a plurality of ions; split the larger trap region into individual trapping regions each containing a portion of the plurality of ions; and eject ions from the trapping regions.

An ion separation apparatus comprises: (a) first and second ion carpets, each comprising: a substrate having first and second faces; and a set of electrodes disposed on or beneath the first face, wherein a configuration of a first plurality of the set of electrodes defines at least one group of circle sectors; (b) an ion exit aperture passing through one ion carpet; and (c) one or more power supplies configured to provide radio frequency voltages to a first subset of the electrodes of each ion carpet, to provide electrical potential differences across electrodes of the first subset of electrodes of each ion carpet, and to provide time-varying voltages to the first plurality of electrodes of each ion carpet that migrate through the sectors as a traveling wave, wherein the ion carpets are disposed parallel to one another with a gap therebetween, the first faces facing one another across the gap.

The invention generally relates to systems and methods for isolating a target ion in an ion trap. In certain aspects, the invention provides a system that includes a mass spectrometer having an ion trap, and a central processing unit (CPU). The CPU includes storage coupled to the CPU for storing instructions that when executed by the CPU cause the system to apply a dual frequency waveform to the ion trap that ejects non-target ions from the ion trap while retaining a target ion in the ion trap.

Methods and systems for FTMS-based analysis having an improved duty cycle relative to conventional FTMS techniques are provided herein. In various aspects, the methods and systems described herein operate on a continuous ion beam, thereby eliminating the relatively long duration trapping and cooling steps associated with Penning traps or orbitraps of conventional FTMS systems, as well as provide increased resolving power by sequentially interrogating the continuous ion beam under different radially-confining field conditions.

A mass selective ion trapping device includes a linear ion trap and a RF control circuitry. The ion trap includes a plurality of trap electrodes configured for generating a quadrupolar trapping field in a trap interior and for mass selective ejection of ions from the trap interior. The RF control circuitry is configured to apply a balanced AC voltage to the trap electrodes during a first period of time such that an AC voltage applied to a first pair of trap electrodes is of the same magnitude and of opposite sign to an AC voltage applied to a second pair of trap electrodes; apply unbalanced RF voltage to the second pair of trap electrodes during a second period of time; ramp the balanced AC voltage down and the unbalanced RF voltage up during a transition period; and eject ions from the linear ion trap after the second period of time.

Devices and methods for surface-induced association are disclosed herein. According to one embodiment, a device for surface-induced dissociation (SID) includes a collision surface and a deflector configured to guide precursor ions from a pre-SID region to the collision surface. In some embodiments, an extractor extracts ions off the collision surface after collision with the collision surface. In some embodiments, an RF device can collect and/or transmit the extracted ions. In some embodiments, an ion funnel guides product ions resulting from collision with the collision surface to a post-SID region. Some aspects of the disclosure are directed to methods for surface-induced dissociation, which may in some embodiments include using of a split lens or an ion funnel.

An electrostatic linear ion trap (ELIT) array includes a plurality of ion mirrors and a plurality of elongated charge detection cylinders each defining an axial passageway centrally therethrough, the ion mirrors and the charge detection cylinders arranged relative to one another such that each charge detection cylinder is positioned between a different respective pair of the ion mirrors with the respective axial passageways of each coaxial with one another, wherein the axial passageways of the ELITs are not coaxial with one another, means for selectively directing at least one ion into each of the plurality of ELITs, and means for controlling each of the ion mirrors in a manner which causes the at least one ion in at least two of the ELITs to become trapped therein and to simultaneously oscillate back and forth between the respective ion mirrors each time passing through the respective charge detection cylinder.

A gas chromatograph mass spectrometer includes a gas chromatograph part including a separation column, a mass spectrometer part, and a controller configured to control at least an ionization part of the mass spectrometer part. The ionization part includes an ion source box having a space for ionizing the components flowing out from an outlet of the separation column in the inside, a heater for adjusting a temperature of an ion source box, and a filament that is arranged outside of the ion source box and generates an electron for ionizing the components flowing out from the outlet of the separation column. The controller is configured to, after applying voltage to the filament, adjust a temperature of the ion source box affected by heat emitted from the filament to a predetermined temperature by controlling output of the heater in relation to magnitude of heat generation of the filament.