Disclosed herein is an ion guide for guiding an ion beam along an ion path, said ion guide having a longitudinal axis which corresponds to said ion path. Said ion guide comprises a plurality of electrode plates which are arranged perpendicularly to the longitudinal axis, each electrode plate having an opening and being arranged such that said longitudinal axis extends through its respective opening, wherein said openings collectively define an ion guide volume. The ion guide extends or is configured to extend through a separation wall separating adjacent first and second pumping chambers. The ion guide has a first portion, in which gaps are formed between at least some of said electrode plates such that uncharged gas can escape from said ion guide volume, wherein said first portion is completely located in said first pumping chamber. A second portion, in which sealing elements are arranged between adjacent electrode plates, prevents neutral gas from escaping from that portion of the ion guide volume between adjacent electrode plates, said second portion extends at least from said separation wall into said second pumping chamber.

An interface transports ions from a first pressure environment to a lower pressure analysis instrument and may include a first region pumped to a second pressure less than the first pressure, a first ion funnel disposed in the first region, a first ion carpet in the first region opposite an ion outlet end of the first ion funnel, a second region pumped to a third pressure less than the second pressure and greater than the instrument pressure, a second ion funnel disposed in the second region and a second ion carpet in the second region opposite an ion outlet end of the second ion funnel. Ions from the environment pass sequentially through the first and second ion funnels and into the analysis instrument. Each of the first and second ion funnels define a tapered axial passageway therethrough each defining a respective virtual jet disrupter therein.

An ion funnel device is disclosed. A first pair of electrodes is positioned in a first direction. A second pair of electrodes is positioned in a second direction. The device includes an RF voltage source and a DC voltage source. A RF voltage with a superimposed DC voltage gradient is applied to the first pair of electrodes, and a DC voltage gradient is applied to the second pair of electrodes.

An interface for receiving ions in a carrier gas from an atmospheric pressure ion source at a spectrometer that is configured to analyse the received ions at a lower pressure includes an interface vacuum chamber having a downstream aperture; a support assembly defining an axial bore arranged to allow a removable capillary tube to extend therethrough; ions being received from the atmospheric pressure ion source through the capillary tube and directed towards the downstream aperture; and a jet disruptor, positioned downstream from the axial bore and configured to disrupt gas flow between the axial bore and the downstream aperture only when the capillary tube is not fully inserted through the axial bore.

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.

Instruments are disclosed for analyzing ions from about 1000 to 10,000,000 Daltons by controlling a gaseous medium through which the ions travel under the influence of an electric field so that properties of the ions, such as diameter, electrical mobility, and charge, are measured. One embodiment of the disclosed instruments includes an ion source, a nozzle, a jet relaxation region, an ion accumulation region, an electronic gate, a flow chamber and an ion detector.

A system for transporting ions includes: an ion transfer tube having an axis and an internal bore having a width and a height less than the width; and an apparatus comprising a plurality of electrodes, each having a respective ion aperture having an aperture center, the apertures defining an ion channel configured to receive the ions from the ion transfer tube and to transport the ions to an outlet end of the apparatus, wherein at least a subset of the apertures progressively decrease in size in a direction towards the apparatus outlet end, wherein the ion transfer tube is configured such that the ion transfer tube axis is non-coincident with an axis of the ion channel or such that the width dimension of the ion transfer tube bore is parallel to a plane defined by the ion transfer tube axis and the ion channel axis.

An instrument for separating ions may include an ion source in a first pressure environment at a first pressure and configured to generate ions from a sample, an ion separation instrument, controlled to an instrument pressure that is less than the first pressure, and configured to separate ions as a function of at least one molecular characteristic and an interface, controlled to a second pressure less than the first pressure and greater than the instrument pressure, for transporting the generated ions from the first pressure environment into the ion separation instrument operating at the instrument pressure. The interface may include a sealed ion funnel defining an axial passageway therethrough, and an ion carpet sealed to the first ion funnel. A portion of the axial passageway tapers from a first cross-sectional area to a reduced cross-sectional area such that the tapered axial passageway defining a virtual jet disrupter therein.

A method of reducing fragmentation of ions generated from a sample during transport of the ions through an ion transport apparatus that comprises an ion funnel portion, comprises: applying a selected DC potential difference between an outlet end of the ion transport apparatus and an exit ion lens that is disposed adjacent to the outlet end, wherein a sign of the selected DC potential difference is chosen so as to accelerate the ions from the outlet end of the ion transport apparatus towards and through the exit ion lens.

The invention relates to hybrid IMS/MS systems and provides hybrid IMS/MS system comprising an RF funnel, an ion mobility analyzer and a mass analyzer wherein the RF funnel is arranged non-collinearly to the ion mobility analyzer, preferably a TIMS analyzer (TIMS=trapped ion mobility spectrometry).