An ion source includes an electron generator, an ionization chamber, and a magnetic field. The electron generator is configured to produce electrons. The ionization chamber has an electron entrance aperture through a first wall, an ion exit aperture through a second wall, and an axis. The ionization chamber is configured to produce ions. The magnetic field is arranged to confine electrons in a beam directed through the electron entrance aperture, in a direction within 45 degrees of parallel to the axis, and towards a location displaced from the ion exit aperture.

The present invention addresses ways to facilitate the detection and analysis of ion abundance, in particular for analysis of elemental ions, and in particular embodiments for isotope ratio analysis, by use of collision cells that employ an axial drag field, i.e. an axial electric field that exerts a drag force on ions within the cell. By means of the invention, the drag field allows an increase in the transmission in the case of Li from a few % up to almost 100%. The drag field is generated by electric fields and can be switched on and off within microsecond (μs) timescales and thus improves the sensitivity for the lighter elements dramatically. The invention allows use of collision cells for analysis of elemental ions in a simple and fast workflow with high throughput and without compromising transmission.

A tip including an alloy of platinum and an alloying element chosen from gold, palladium, ruthenium, osmium, iron, cobalt, nickel, copper, zinc, silver, chromium, manganese, titanium, niobium, scandium, vanadium, yttrium, zirconium, molybdenum, tantalum, tungsten, technetium, cadmium, hafnium, rhenium, less than 5 wt. % of iridium, less than 5 wt. % of rhodium, greater than 20 wt. % iridium, greater than 20 wt. % rhodium, and a combination thereof, relative to the total weight of the alloy is disclosed. An interface cone can include a base and the tip.

A coupling for connecting together vacuum-based analytical systems requiring to be vibrationally isolated, comprising: a tubular connector having a longitudinal axis, the connector comprising a first end for connection to a first analytical system and a flexible portion reducing transmission of vibrations and permitting displacement of the first analytical system in a direction transverse to the longitudinal axis of the connector; and a seal longitudinally separated from the flexible portion, for vacuum sealing between the connector and a second analytical system; wherein the connector contains ion optics for transmitting ions between the first and second analytical systems.

The present disclosure is directed to an ion funnel and associated systems, where the ion funnel includes a plurality of electrodes each define an opening having an associated inner dimension and receive a RF voltage. The associated inner dimensions progressively reduce in size from approximately a first inner dimension to approximately a second inner dimension. The electrodes define an internal chamber having an outer dimension that reduces at a convergence angle of approximately 30 degrees for at least a majority of a length of the internal chamber from the first inner dimension to the second inner dimension. Additional systems and methods are provided for transferring ions from an ion funnel to an ion mobility device having a pressure greater than that of the ion funnel, for selectively transferring ions from the ion funnel to the ion mobility device, and for stripping ions of certain molecules adducted thereto during transfer.

An electron-ion interaction module for use in a mass spectrometer, having a plurality of rod sets arranged relative to one another such that said rod sets share a common longitudinal axis and each of said rod sets is longitudinally separated from an adjacent rod set by a gap, each of said rod sets comprising a plurality of rods arranged around said common longitudinal axis. The module further includes at least one magnet disposed around said rod sets so as to at least partially surround one or more of said plurality of rod sets and configured to generate a static magnetic field along said longitudinal axis. The rod sets are configured to receive electrons from an electron source and ions from an ion source within an interaction volume defined by the rods. One or more RF voltage sources coupled to the plurality of rod sets applies voltages to the rods.

An ion guide includes a plurality of lenses arranged in series along a curved central axis. Each lens includes a body and a central opening, and the central openings of the plurality of disks define a curved ion guide region. The ion guide includes an ion deflector configured to apply a radial DC electric field across the ion guide region and along the curved central axis. The ion deflector includes at least one DC voltage source that is configured to apply a positive DC voltage to at least some of the plurality of lenses and a negative DC voltage to at least some of the plurality of lenses.

A secondary ion mass spectrometer comprising a primary ion beam device, and means for collecting, mass filtering and subsequently detecting secondary ions released from a sample due to the sample having been impacted by a plurality of primary ion beams. The secondary ion mass spectrometer is remarkable in that it uses a plurality of primary ion beams in parallel for scanning the surface of the sample.

The present invention relates to an assembly comprising a vacuum chamber and a time-of-flight mass spectrometer wherein the time-of-flight mass spectrometer is contained within the vacuum chamber. The time-of-flight mass spectrometer comprising a first electrode and a second electrode, the second electrode being spaced apart from the first electrode at a distance defining a portion of an ion-flight path therebetween. The assembly further comprising a first support for supporting the first electrode, the first support arranged between an inner surface of the vacuum chamber and the first electrode. The first support is configured to permit relative movement between at least a portion of the inner surface of the vacuum chamber and the first electrode. The inner surface of the vacuum chamber and the first electrode are thermally coupled. The present invention also relates to a multi-reflection time-of-flight mass analyser. The present invention also relates to an apparatus for out-gassing to remove contaminants from surfaces within a vacuum chamber by heating and subsequently cooling the surfaces.

A mass spectrometry method comprises: storing a first packet of ions within an ion storage apparatus; transferring the first ion packet into an electrostatic trap mass analyzer through a set of electrostatic lenses, wherein, during the transfer, either the lenses are operated in a first mode of operation or an injection voltage of a first pre-determined magnitude is applied to an electrode of the mass analyzer; mass analyzing the first ion packet using the mass analyzer; storing a second packet of ions within the ion storage apparatus; transferring the second ion packet into the mass analyzer through the set of lenses, wherein, during the transfer, either the lenses are operated in a second mode of operation or an injection voltage of a second pre-determined magnitude is applied to the electrode of the mass analyzer; and mass analyzing the second packet of ions using the electrostatic trap mass analyzer.