WO2020021255A1 - Interface de transfert d'ions pour sm - Google Patents

Interface de transfert d'ions pour sm Download PDF

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Publication number
WO2020021255A1
WO2020021255A1 PCT/GB2019/052066 GB2019052066W WO2020021255A1 WO 2020021255 A1 WO2020021255 A1 WO 2020021255A1 GB 2019052066 W GB2019052066 W GB 2019052066W WO 2020021255 A1 WO2020021255 A1 WO 2020021255A1
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WO
WIPO (PCT)
Prior art keywords
ion
ion guide
spectrometer
gas
guide
Prior art date
Application number
PCT/GB2019/052066
Other languages
English (en)
Inventor
Anatoly Verenchikov
Original Assignee
Micromass Uk Limited
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Micromass Uk Limited filed Critical Micromass Uk Limited
Priority to GB2014485.3A priority Critical patent/GB2588292B/en
Publication of WO2020021255A1 publication Critical patent/WO2020021255A1/fr

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/06Electron- or ion-optical arrangements
    • H01J49/062Ion guides
    • H01J49/063Multipole ion guides, e.g. quadrupoles, hexapoles
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/06Electron- or ion-optical arrangements
    • H01J49/067Ion lenses, apertures, skimmers
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/06Electron- or ion-optical arrangements
    • H01J49/068Mounting, supporting, spacing, or insulating electrodes
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/24Vacuum systems, e.g. maintaining desired pressures
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/26Mass spectrometers or separator tubes
    • H01J49/34Dynamic spectrometers
    • H01J49/40Time-of-flight spectrometers
    • H01J49/401Time-of-flight spectrometers characterised by orthogonal acceleration, e.g. focusing or selecting the ions, pusher electrode

Definitions

  • the invention relates to the area of time-of-flight (TOF) mass spectrometers, such as multi-reflecting time-of-flight (MRTOF) mass spectrometers, and is particularly concerned with the ion transfer interface to the TOF region.
  • TOF time-of-flight
  • MTOF multi-reflecting time-of-flight
  • Time-of-flight mass spectrometers are widely used for their combination of sensitivity and speed, and lately with the introduction of various multi-pass schemes, for their high resolution and mass accuracy.
  • the resolution of TOF MS analyzers has been substantially improved by using multiple ion passes in multi-pass TOFMS (MPTOF) instruments.
  • MTOF multi-reflecting TOF
  • These instruments have either ion mirrors for multiple ion reflections (i.e. a multi-reflecting TOF (MRTOF)), such as described in SU1725289, US6107625, US6570152, GB2403063, and US6717132, or between have electrostatic sectors for multiple ion turns (i.e. a multi-turn TOF (MTTOF)) such as described in US7504620 and US7755036.
  • MTOF multi-reflecting TOF
  • W09103071 proposed an orthogonal accelerator for coupling a reflecting TOF MS analyzer with a continuous ion source.
  • a continuous ion beam enters an orthogonal accelerator (OA) in a first direction.
  • Periodic electrical pulses are used to extract ion packets in an orthogonal direction.
  • the duty cycle of the pulsed conversion is strongly enhanced by using long ribbons of continuous ion beams.
  • emittance the product of ion beam width and angular divergence, called emittance, defines the balance between time and energy spreads of ion packets.
  • the beam emittance defines the lowest reachable turn around time (TAT), in turn, being one major limit of the TOF MS resolving power.
  • the axial energy spread of the continuous beam (along the beam) defines the angular divergence of orthogonally extracted ion packets, being important for MR TOF MS transmission, where meniscus angular divergence of a few mrad still induces ion losses at prolonged ion paths.
  • OA-TOF MS and OA-MRTOF MS performances are defined and limited by parameters of continuous ion beams formed within upstream ion transfer interfaces.
  • OA-TOF MS are widely used in combination with gaseous ion sources like Electrospray (ESI), Atmospheric pressure ionization (APPI), atmospheric Pressure Chemical Ionization (APCI), Inductively coupled Plasma (ICP) and gaseous (MALDI) ion sources.
  • Ion transfer interfaces are used to deliver ions from gas filled (mostly atmospheric) ion sources into the OA located at deep vacuum. Transfer interfaces are arranged with multiple stages of differential pumping and employ radio-frequency (RF) ion guides at intermediate gas pressures, followed by a lens transfer optics in a deeper vacuum, the latter of which shape the ion beam before the OA.
  • RF radio-frequency
  • the interface performance defines ion beam parameters, which in turn limit the performance of the OA-TOF MS, as explained in the previous section.
  • Gas filled RF ions guides became an intrinsic part of transfer interfaces since the l990s, after discovering advantages of collisional ion dampening within radially confining RF guides, initially quadrupoles, proposed in US4963736. Collisional dampening strongly improves ion beam emittances and energy spreads for better ion admission by various MS systems.
  • ion guides are placed within intermediate pumping stages at ⁇ l OmTorr gas pressures.
  • RF ion guides are terminated by fine apertures (usually lmm or less) for limiting gas flow into downstream ion optics in the next vacuum stage.
  • fine apertures usually lmm or less
  • Relatively strong extracting fields (few Volts/mm) at the ion guide exit help nearly full ion transmission through the exit aperture.
  • the extracted ion beam is then shaped within a lens system for injection into an OA of a TOF MS. Problems of conventional ion beam extraction through fine apertures are detailed in the specification.
  • Lens systems of commercial OA-TOF MS are characterized by a number of common features.
  • a fine (lmm) exit aperture at the end of the ion guide serves for reducing the gas downstream of the ion guide.
  • the ion extraction is arranged to form ion focusing at the aperture plane.
  • the downstream lens optics starts from a point ion source and forms a nearly parallel ion beam at the entrance slit of the OA converter.
  • the lens magnifies the spatial ion spread while reducing angular ion spread for a smaller turn around time downstream of the OA.
  • the lens system comprises at least one short focusing lens, which is highly chromatic (i.e.
  • the periodic Einzel lens is long known in nuclear physics, as described in: "The current transmission of a periodic electrostatic lens system", W. Huizenga and W. Schuurman, J. Nuclear Energy, Part C, Plasma Physics, Accelerators, Thermonuclear Research, v.6, No5, 1964.
  • the theory of periodic lens is based on transformation matrices, defining phase-space transformation and stability conditions, and can be found e.g. in "Principles of Charged Particle Acceleration", Stanley Humphries, 2015, Science, originally published in 1986, or in H. Wollnik, "Optics of Charged Particles", Acad. Press, Orlando, FL (1987).
  • Nonlinear effects and fundamental stability in effective potential terms are described in "Stable ion beam transport through periodic electrostatic structures: linear and non-linear effects", A. Verentchikov et. al, Science Direct, Physics Procedia, 1 (2008) 87- 97.
  • a periodic lens system provides stable and indefinite ion beam confinement, and may be controlled with a single voltage, applied to periodically repeated lens elements, where a second different potential may be at ground.
  • the periodic lens is long known, however, it was never applied as a lens system between RF ion guides and an OA in a TOF MS for multiple practical reasons, including: (i) lens termination on both ends would be suspected to distort the phase space of the ion beam; (ii) non-linear lens effects may spread and swirl the beam phase space; (iii) advantages for use were not apparent; and (iv) a multi- element system would naturally be viewed as being more complex mechanically.
  • ion transfer interfaces for TOF and MRTOF mass spectrometers with orthogonal accelerators employ RF ion guides and lens systems.
  • the interfaces of the prior art are characterized by distortion of the ion beam parameters, producing ion beams with higher energy spread and emittances compared to ion beam parameters obtained using collisional dampening of the ions in RF ion guides at intermediate gas pressures, meaning that the interfaces are distorting the collisional dampened ion beams. This in turn limits the resolution and sensitivity of the TOF MS and MRTOF MS.
  • the present invention provides a mass or mobility spectrometer comprising:
  • At least one vacuum pump for differentially pumping the pumping stages such that the second pumping stage is at a lower pressure than the first pumping stage
  • an ion guide extending continuously from the first pumping stage to the second pumping stage, through the orifice, such that an upstream end of the ion guide is in the first pumping stage and a downstream portion of the ion guide is in the second pumping stage; wherein the ion guide comprises a plurality of electrodes for radially confining ions and wherein the electrodes define radially extending gaps therebetween;
  • the gaps are open such that gas is evacuated, in use, radially out of the downstream portion through said gaps;
  • the gaps are either: (i) blocked such that gas cannot be evacuated radially at the upstream end; or (ii) restricted relative to the gaps in said downstream portion of the ion guide for restricting the evacuation of gas radially at the upstream end.
  • the ion guide may simultaneously enable both a high pressure within the ion guide at the upstream end and a low pressure within the ion guide at the downstream portion. This enables collisional damping of the ions entering the ion guide in the first pumping stage so that these ions are conditioned for transport through the ion guide into the second, lower pressure pumping stage. This may also enable substantially collision-free passage of the ions at the downstream portion, e.g. such that the ions are conditioned for downstream transmission through an aperture and/or into a mass or mobility analyser.
  • an ion guide it is known to arrange an ion guide to extend continuously between adjacent pumping stages, such that the ion guide replaces the conventional differential pumping aperture arranged between such pumping stages and hence minimises ion losses (e.g. see Fig. 1).
  • the ion guide is supported at the junction between the two pumping stages by an insulating support structure.
  • the gaps at the upstream end may be blocked or restricted such that, in use, the pressure within the upstream end is higher than the pressure within the rest of the ion guide and causes the ions to be collisionally dampened, whereas the gaps in the downstream portion are open such that the gas is radially evacuated and the pressure therein is such that ions passing therethrough substantially do not collide with gas molecules or collide with gas at a lower rate than in the upstream end portion.
  • ⁇ x% of the ions may collide with gas molecules within the
  • x is selected from: 1; 2; 3; 4 or 5.
  • the pumping stages are evacuated by the at least one vacuum pump. It will be appreciated that it is one of the at least one vacuum pumps that radially evacuates the gas from the downstream portion of the ion guide.
  • the multiple pumping stages comprise multiple respective vacuum chambers that are evacuated through respective gas exhaust ports by the at least one vacuum pump.
  • the multiple pumping stages are differentially pumped such that stages located further in the downstream direction (away from the ion source and towards the mass or mobility analyser) are pumped to lower pressures.
  • the at least one vacuum pump therefore evacuates the gas from within the ion guide.
  • Said gaps at the upstream end of the ion guide may be blocked or restricted from a point at the distal upstream end of the ion guide and for a length downstream thereof.
  • the gaps in the upstream end are not blocked, and instead gas can be evacuated radially from the upstream end.
  • gas will be radially evaluated from the upstream end at a lower rate than from the downstream portion.
  • the gaps in the upstream end may be restricted relative to the gaps in the
  • the gaps between adjacent electrodes in the upstream end being made narrower (orthogonal to the radial direction) than in the downstream portion, such that the gas flow through the gaps is more restricted.
  • the upstream direction referred to herein means in a direction towards the ion source (i.e. the opposite direction to the ion flow).
  • spectrometer described may comprise an ion source such as a gaseous ion source.
  • Each of the plurality of electrodes of the ion guide may extend continuously from an upstream distal end of the ion guide to a downstream distal end of the ion guide. In other words, the ion guide is not axially segmented.
  • the ion guide may further comprises: an intermediate sealed portion between the upstream end and the downstream portion, wherein the gaps of the intermediate sealed portion are blocked such that gas cannot be radially evacuated from within the intermediate sealed portion; and an intermediate open portion between the upstream end and the intermediate sealed portion, wherein the gaps of the intermediate open portion are open such that gas is evacuated, in use, from within the intermediate open portion through said gaps.
  • the gaps in the intermediate sealed portion (and/or the upstream end) of the ion guide may be blocked by a seal extending circumferentially around the outside of the electrodes such that gas cannot be radially evacuated from that portion; or the gaps may be blocked by plugs located in the gaps between the electrodes.
  • the seals or plugs described herein may be an electrically insulating material so that they do not electrically connect the electrodes of the ion guide that are in contact with them.
  • the gaps of the intermediate sealed portion may be restricted relative to the gaps of the downstream portion of the ion guide.
  • the intermediate sealed portion may extend axially upstream and/or downstream from said orifice.
  • the intermediate sealed portion may have an axial length selected from the group of: >l0D, where D is the inscribed diameter of said ion guide; > 20 mm; > 30 mm; > 40 mm; > 50 mm; and > 60 mm; and/or the intermediate sealed portion may have an axial length Lc, wherein the ion guide has an inscribed diameter D, and wherein D 3 /L c ⁇ 1 mm 2 .
  • the gas pressure at the upstream entrance of the intermediate sealed portion may be arranged low enough such that the gas mean free path Xg > D, for suppression of gas conductance through the channel of the intermediate sealed portion by a factor L c /D, where Lc is the axial length of the intermediate sealed portion and D is the inscribed diameter of said ion guide.
  • downstream distal end of the ion guide may be located in the second pumping stage, or alternatively, that the ion guide may continuously extend through one or more further pumping stage arranged downstream of the second pumping stage.
  • there will be one or more further orifice between the pumping stages and one or more further intermediate sealed portion may be provided extending axially upstream and/or downstream from each of the one or more further orifice.
  • the radially extending gaps in the axial portion of ion guide between the intermediate sealed portions may be open such that gas is evacuated, in use, from within these portions through the gaps.
  • the axial portion of the ion guide immediately downstream of the most downstream sealed portion may be open such that gas is evacuated, in use, from within this portions through its gaps.
  • the upstream distal end of the ion guide may be spaced from the upstream wall and downstream wall of the first pumping stage.
  • the upstream end of the ion guide (having blocked or restricted radially extending gaps) does not correspond to a portion of an ion guide that extends through an orifice in a wall between two pumping stages.
  • the upstream distal end of the ion guide therefore may not be upstream of the first pumping stage.
  • the ion guide may not pass through or reside within a differential pumping aperture in an upstream wall of the first pumping stage.
  • the spectrometer may be configured such that, in use, a pressure within the upstream end is > 10 mTorr and/or a pressure within the downstream end of the ion guide is ⁇ 1E-6 Torr; and/or such that the ratio of the pressure within the upstream end P A to the pressure within the downstream end portion P D is RA/R O 3 1E+4.
  • the portion of the ion guide at the upstream end having said blocked or restricted gaps may have an axial length selected from the group of: > 5 mm; > 10 mm; > 15 mm; >
  • the downstream portion may have an axial length of >l0D, where D is the inscribed diameter of said ion guide; and/or the downstream portion may have an axial length selected from the group of: > 20 mm; > 30 mm; > 40 mm; > 50 mm; and > 60 mm.
  • the downstream portion may have an axial length L D > D 2 !2h for sufficient gas evacuation, wherein h is the minimum width of the open gaps, perpendicular to the radial direction of the ion guide, and D is the inscribed diameter of said ion guide.
  • each gap defined between adjacent electrodes of the ion guide, in at least the upstream end and/or intermediate sealed portion may be at least three times the minimum width h of the gap, perpendicular to the radial direction of the ion guide. This relatively long and narrow gap helps prevent stray ions from charging the seal that blocks the exit of the gap in the upstream end and/or intermediate sealed portion.
  • the inscribed diameter D of said ion guide may be between 2 and 5 mm, or about 3 mm.
  • the inscribed diameter may be constant along the entire length of the ion guide.
  • the gaps in the upstream end of the ion guide may be blocked by a seal extending circumferentially around the outside of the electrodes such that gas cannot be radially evacuated from within the upstream end; or wherein the gaps in the upstream end of the ion guide are blocked by plugs located in the gaps between the electrodes.
  • the seal or plugs may be an electrically insulating material so that they do not electrically connect the electrodes of the ion guide that are in contact with them.
  • the ion guide may be a multipole RF ion guide having rod electrodes, such as a quadrupole ion guide.
  • RF voltage supplies are connected to the electrodes of the RF ion guide so as to supply the RF voltages for radially confining the ions.
  • the spectrometer may further comprise a lens system arranged downstream of the ion guide for shaping the ion beam received therefrom, wherein the ion path from the ion guide into the lens system is free from apertures having a diameter that is less than the inscribed diameter of said ion guide.
  • the lens system may comprise electrodes defining an inscribed diameter that is at least twice as large as the inscribed diameter of the ion guide.
  • the lens system may comprise a plurality of DC electrodes spaced along a longitudinal axis on which ions are received from the ion guide, and DC voltage supplies configured to apply different DC potentials to different ones of said DC electrodes such that when ions travel through the lens system along the longitudinal axis they experience an ion confining force, generated by the DC potentials, in at least one dimension orthogonal to the longitudinal axis.
  • the plurality of DC electrodes may be apertured electrodes having apertures through which the ions travel as they pass along the longitudinal axis.
  • each DC electrode may be an annular ring electrode or may be a segment of an annulus (i.e. an annular strip).
  • the DC voltage supplies may be configured to maintain adjacent DC electrodes at different DC potentials, and alternating DC electrodes at the same DC potential.
  • One of the DC potentials may be a ground potential; optionally wherein the DC electrodes at the distal ends of the lens system are maintained at ground potential in use.
  • the DC electrode at one or both longitudinal ends of the lens system may have a length, in the longitudinal direction, that is longer than the length of each DC electrode arranged between the end electrodes.
  • the lens system may pass between at least two differentially pumped stages of the spectrometer.
  • the spectrometer may comprise a heater for heating electrodes of the lens system.
  • the downstream end electrode of the lens system may comprise the differential pumping aperture between two pumping stages. This electrode may be heated by the heater.
  • the ion guide and/or lens system may have a curved longitudinal axis for guiding ions in a curved path.
  • The may comprise a mass or mobility analyser arranged to receive ions from the ion guide or lens system.
  • the mass analyser may be a time of flight mass analyser comprising an orthogonal ion accelerator arranged to receive the ions from the ion guide or lens system.
  • the time-of-flight mass analyser may be: (i) a multi-reflecting time of flight mass analyser having two ion mirrors that are elongated in a drift direction and configured to reflect ions multiple times in an oscillation dimension that is orthogonal to the drift direction, wherein the orthogonal ion accelerator is arranged to receive ions and accelerate them into one of the ion mirrors; or (ii) a multi-turn time of flight mass analyser having at least two electrostatic sectors configured to turn ions multiple times in an oscillation plane, wherein the orthogonal accelerator is arranged to receive ions and accelerate them into one of the sectors.
  • the present invention also provides a method of mass spectrometry or ion mobility spectrometry comprising: providing a spectrometer as described herein above; operating the at least one vacuum pump so as to evacuate gas from the ion guide such that the pressure within the upstream end portion of the ion guide is higher than the pressure within the rest of the ion guide; transmitting ions through the ion guide, wherein the ions are collisionally dampened by gas in the upstream end portion but substantially do not collide with gas molecules in the downstream portion, or collide with gas at a lower rate in the downstream portion than in the upstream end portion; and mass analysing or ion mobility analysing ions downstream of the ion guide.
  • the upstream end portion of the ion guide (or all portions thereof) need not have gaps that are blocked or restricted.
  • the upstream end portion of the RF ion guide may instead protrude into an upstream pumping stage such that the upstream end portion is at the higher pressure (as compared to the downstream portion in the downstream pumping stage) required to perform the collisional damping.
  • the present invention also provides a time of flight mass spectrometer comprising: first, second and third interconnected pumping stages; at least one vacuum pump for evacuating the pumping stages; an ion guide continuously extending from first pumping stage to the second pumping stage; an orthogonal ion accelerator and at least one ion mirror or electrostatic sector arranged in the third pumping stage, wherein the orthogonal ion accelerator is configured to pulse ions into the ion mirror or electrostatic sector; and a lens system between the ion guide and orthogonal ion accelerator, wherein the ion path from the ion guide into the lens system is free from apertures having a diameter that is less than the inscribed diameter of said ion guide.
  • the spectrometer may have any of the features described above in relation to the first aspect, except that the upstream end of the ion guide need not have gaps that are blocked or restricted.
  • the pressure within the upstream end portion may be > 10 mTorr and/or the pressure within the downstream end portion of the ion guide may be ⁇ 1E-6 Torr; and/or the ratio of the pressure within the upstream end portion P A to the pressure within the downstream end portion P D may be R A /R O 31E+4.
  • Further pumping stages may be provided between the first and second pumping stages, and the ion guide may continuously extend through those further pumping stages.
  • the spectrometer may be configured such that the at least one vacuum pump pumps the first and second pumping stages such that, in use, the pressure within the upstream end portion of the ion guide is higher than the pressure within a downstream end portion of the ion guide and such that the ions are collisionally dampened in the upstream end portion but substantially do not collide with gas molecules in the downstream end portion, or collide with gas at a lower rate than in the upstream end portion.
  • the lens system may comprise a plurality of DC electrodes spaced along a longitudinal axis on which ions are received from the ion guide, and DC voltage supplies configured to apply different DC potentials to different ones of said DC electrodes such that when ions travel through the lens system along the longitudinal axis they experience an ion confining force, generated by the DC potentials, in at least one dimension orthogonal to the longitudinal axis.
  • the lens system may comprise electrodes defining an inscribed diameter that is at least twice as large as the inscribed diameter of the ion guide.
  • the plurality of DC electrodes may be apertured electrodes having apertures through which the ions travel as they pass along the longitudinal axis.
  • each DC electrode may be an annular ring electrode or may be a segment of an annulus (i.e. an annular strip).
  • the DC voltage supplies may be configured to maintain adjacent DC electrodes at different DC potentials, and alternating DC electrodes at the same DC potential.
  • One of the DC potentials may be a ground potential; optionally wherein the DC electrodes at the distal ends of the lens system are maintained at ground potential in use.
  • the DC electrode at one or both longitudinal ends of the lens system may have a length, in the longitudinal direction, that is longer than the length of each DC electrode arranged between the end electrodes.
  • the lens system may pass between at least two differentially pumped stages of the spectrometer, e.g. between the second and third pumping stages.
  • the spectrometer may comprise a heater for heating electrodes of the lens system.
  • the downstream end electrode of the lens system may comprise the differential pumping aperture between two pumping stages. This electrode may be heated by the heater.
  • the ion guide and/or lens system may have a curved longitudinal axis for guiding ions in a curved path.
  • the spectrometer may comprise a mass or mobility analyser arranged to receive ions from the ion guide or lens system.
  • the time-of-flight mass spectrometer may comprise: (i) a multi-reflecting time of flight mass analyser having two ion mirrors that are elongated in a drift direction and configured to reflect ions multiple times in an oscillation dimension that is orthogonal to the drift direction, wherein the orthogonal ion accelerator is arranged to receive ions and accelerate them into one of the ion mirrors; or (ii) a multi-turn time of flight mass analyser having at least two electrostatic sectors configured to turn ions multiple times in an oscillation plane, wherein the orthogonal accelerator is arranged to receive ions and accelerate them into one of the sectors.
  • the second aspect also provides a method of time of flight mass spectrometry comprising: providing a time of flight spectrometer as described herein; operating the at least one vacuum pump so as to evacuate gas from the ion guide such that the pressure within the upstream end portion of the ion guide is higher than the pressure within the rest of the ion guide; transmitting ions through the ion guide, wherein the ions are collisionally dampened by gas in the upstream end portion but substantially do not collide with gas molecules in the downstream end portion, or collide with gas at a lower rate in the downstream end portion than in the upstream end portion; transmitting the ions to the orthogonal ion accelerator using the lens system; and pulsing the ions into the ion mirror or sector for time of flight mass analysing the ions.
  • ion extraction from gas filled RF ion guides distort the ion beam parameters by a strong extracting field at the presence of fringing RF fields and at the presence of gas collisions; extraction through fine apertures produces surface charging (say, of oil or droplet coated metal); extraction through a fine aperture forms a short-focusing lens being highly chromatic and having large aberrations; coupling between RF ion guides and lens systems are not optimized; lens systems are not robust, they are difficult for tune, and are susceptible to misalignments; lens systems operate at elevated pressures at 1E-4 to lE-5Torr, spreading the ion beam in gas collisions; if using beam collimators for limiting ion beam phase space, the effect of ion on surface sliding collisions produce a beam halo.
  • a protruding RF ion guide may be used for non-distorting ion transfer between regions with dampening gas collisions and deep vacuum, if arranging long radially sealed channels, alternated with open areas for gas evacuation, and if optimizing parameters of the ion guide for a substantial pressure drop above a factor of 1E+5 along the ion guide. While the collisional dampening may require gas pressures above lE-lmTorr if using short (e.g.
  • embodiments of the invention propose: (a) arranging alternating segments of radially sealed and open segments of a continuous ion guide (b) a local rise of gas pressure within a first radially sealed channel with continuum gas flow conditions; (c) substantial suppression of gas conductance in the second radially sealed channel at rarified gas flow conditions; and (d) arrangement of sufficient gas conductance in open segments; where ion guide parameters are balanced for satisfying all the requirements and to form a sweet spot range, as described below.
  • the inventor further realized that the optimized protruding ion guide allows using wide extracting apertures and soft extracting fields.
  • the proposed extraction methods and parameters overcome most of the prior art faults and according to simulations, allow reaching unprecedented small emittance of the ion beam, being under 0.5mm*deg at 30eV beam energy, which is three to five times lower compared to reported prior art ion beam parameters.
  • the inventor further realized that using a periodic lens, being novel for TOFMS interfaces, appears an effective replacement for lens systems downstream of RF ion guides for a number of reasons: it is robust since it may be controlled by varying a single voltage; it is insensitive to minor misalignments and does not require ion beam steering; it passes ion beams without non linear distortions and allows retaining small phase space and energy spread of ion beams; it avoids ion on surface scattering; it appears a strong gas flow restrictor; and finally, it can be bent, curved or passed between differential pumping stages.
  • the proposed ion guide and periodic lens may form continuous ion channels with constant radial ion confinement. Both of those components may be bent at large radius (compared to inner diameter), which helps more compact interface packaging, including a spiral interface arranged around a split flow turbo-molecular pump cartridge.
  • a time-of-flight mass spectrometer comprising conventional components: a gaseous ion source, generating an ion beam; a multi-stage differentially pumped ion transfer interface with stages separated by differential apertures; a gas filled radio-frequency (RF) ion guides for collisional dampening and transfer of said ion beam; a lens system for transferring and shaping said ion beam past said ion guide; an orthogonal accelerator for pulsed extracting of ion packets from the ion beam past said lens system; and a singly reflecting, or multi-reflecting, or multi-turn electrostatic analyzer for mass separation of said ion packets;
  • RF radio-frequency
  • one of said RF ion guides satisfies the following range of parameters: a) said RF ion guide is quadrupolar, i.e. composed of four parallel rods, wherein the inner bore between rods with the inscribed diameter d is continuous and non distorted at the entire guide length;
  • the guide comprises at least four segments A to D, formed by electrically insulating radial seals around said rods, alternated with open rod areas having gaps between rods for gas evacuation;
  • the entrance segment A of said RF ion guide has said radial seal, which either serves as a differential aperture, or the segment A resides past a differential aperture and said radial seal has length L
  • next segment B is open (no radial seal) and is arranged for sufficient radial gas evacuation, achieved at segment length g>l0d and at the gap width h between the guide rods being h>d/4
  • the exit segment D is open (no radial seal), it has length L D >d 2 !2h for sufficient gas evacuation, and the gas pressure P D at the segment end is arranged Pi, ⁇ E-6Torr for collisional free ion beam formation in the subsequent lens system;
  • the exit of said ion guide is open and aligned with the entrance of said lens system without using any aperture with diameter less than d.
  • said lens system may be a periodic lens, energized by at least two distinct DC potentials with one potential optionally being at ground; wherein inscribed diameter of said periodic lens is at least twice larger than D.
  • RA/R O >1E+4; wherein the inscribed diameter D of said ion guide may be between 2 and 5mm, preferably 3mm; and wherein D 3 /Lc ⁇ lmm 2 .
  • the gap between electrodes of said quadrupole may be at least three calibers long H: H/h>3.
  • the electrode shape at the entrance of said periodic lens attenuate the filed of said periodic lens to provide for acceleration of continuous ion beam at the exit cross section of said ion guide being less than 10% the beam mean energy at the entrance of said orthogonal accelerator.
  • said periodic lens may be a rigid structure made by cutting conductive tube with electro erosion into two combs; and wherein ends of said periodic lens may be aligned with axis of said RF ion guide and of said orthogonal accelerator.
  • said periodic lens may be heated to at least l50°C for reducing oil deposits on the hot lens surface, this way avoiding surface charging by ions.
  • said periodic lens may pass between at least two differentially pumped stages.
  • said periodic lens may continue through fringing fields and electrode boundaries of said orthogonal accelerator.
  • At least one of said periodic lens or said RF ion guide may be curved.
  • an ion transfer interface between a gaseous ion source and a mass spectrometer comprising
  • Fig-1 shows a prior art time-of-flight mass spectrometer with an orthogonal accelerator (OA-TOF MS), incorporating a protruding RF ion guide within an ion transfer interface, arranged for improved ion transmission and for reduced gas load onto pumping system;
  • OA-TOF MS orthogonal accelerator
  • Fig.2 shows an embodiment of an OA-TOF MS of the present invention, incorporating an ion transfer interface with an improved protruding ion guide, with an optimized ion extraction downstream of the guide, and with a periodic lens for ion transfer - arranged and improved for collisional ion dampening and for the non-distorted ion transfer of the dampened ion beam all the way to orthogonal accelerator;
  • Fig.3 shows an improved protruding RF ion guide, providing pressure drop over 10,000 times to satisfy both sufficient dampening at the guide entrance and collision free vacuum conditions at the guide exit;
  • Fig.4A shows results of ion optical simulations of ion extraction downstream of the RF ion guide through a wide open aperture, while accurately accounting for three- dimensional fields and considering effects of mutual component misalignment;
  • Fig.4B presents graphs summarizing the results of simulations in Fig.4A;
  • Fig.5 shows an embodiment of a periodic lens downstream of the improved ion guide, having a wide open exit at deep vacuum conditions
  • Fig.6A shows results of ion optical simulations of ion beam extraction downstream of the RF ion guide and of ion beam formation within periodic lens systems considering effects of mutual component misalignment
  • Fig.6B presents graphs summarizing the results of simulations in Fig.6A.
  • Fig-7 shows and embodiment of a spiral ion transfer interface arranged around a cartridge multi-stage turbo-molecular pump, arranged for compact interface size.
  • Fig.l shows a prior art OA-TOF MS 100 comprising: a gaseous Electrospray ion source ESI; an ion transfer interface 10; and a TOF mass analyzer 20 with an orthogonal accelerator 24.
  • Ion transfer interface 10 comprises: multiple stages of differential pumping 11-14, interconnected by fine differential pumping apertures and evacuated by pumps Sl- S4; an ion guide 15 (here an RF multipole), continuously extending between stages 12 and 13; a terminating differential aperture 19 downstream of ion guide 15; and a lens 22.
  • the feature of RF ion guide 15 is common for US5689111, US5652427, US6753523, and US7034292, and is claimed to enhance ion transmission, thus reducing requirements on the pumping systems.
  • ions are sampled together with gas from atmospheric pressure ESI source via a set of separating apertures.
  • Pl lTorr
  • P2>50mTorr is claimed as necessary for collisional ion dampening.
  • P4 shall be under lE-6Torr for non-scattered ion transmission in the TOF 20, thus, requiring aperture 19 to have a diameter less than lmm.
  • Ion transmission is claimed to be improved by the RF ion guide 15 extending between vacuum chambers. Gas collisions in RF ion guide 15 help dampen the ion beam diameter and the axial energy and enhance the ion transmission through the channel 17 and through aperture 19.
  • the exiting ion beam 21 is focused by lens 22 into a parallel ion beam 23 at the entrance of OA 24. Ion beam energy is described as being 5eV, while axial energy spread has been measured as being about leV, meaning that lens 22 is strongly chromatic.
  • ion guide 15 The cross section of ion guide 15 is described in US5689111 and is shown in Fig. l.
  • the guide is a hexapole of six rods 16 mounted on the inner surface of an insulating ring 18, which arrangement exposes the insulating surface to stray ions.
  • Channel 17 through ring 18 is depicted short, less than D.
  • the chosen P2>50mTorr gas pressure corresponds to continuous (Vs rarified) gas flow, and an elongation of channel 17 would have minimal effect on gas conductance, while increasing the harm due to a greater amount of exposed insulating surface of ring 18.
  • the radial RF field confines the ion beam to a width it’ being smaller than Z ) , thus, the guide provides nearly full ion transmission for a wide m/z range of ion species.
  • the guide 15 is terminated by aperture 19, which reduces gas load into stage 14, while stated as being sufficient for nearly lossless ion transfer into optics 22.
  • the exit aperture 19 is chosen to be small, in the range of 0.5- lmm, but still sufficient for ion transfer at minimal gas flow into the TOF analyzer 20 to sustain a vacuum better than lE-6Torr.
  • Ions are extracted from the RF guide 15 by DC fields of aperture 19.
  • the extracting fields shall be sufficiently strong to form a short focusing lens in order to transfer the ion beam through the aperture 19, thus forming a widely diverging beam downstream of the aperture.
  • Lens 22 (looking like the Einzel lens of Fig.l) forms a nearly parallel and expanded ion beam 23 at the entrance of the OA 24. Because of the short focal distance at ion extraction into aperture 19, the lens system is very sensitive to minor side misalignments, which requires additional ion beam steering in the lens 22.
  • Prior art interfaces for OA-TOF MS are known to provide nearly 100% ion transmission through the stages at intermediate gas pressures, regardless of whether using protruding RF ion guides of the type described above or using RF guides separated by apertures.
  • Split flow turbo-molecular pumps with multiple ports allow economic arrangement of multiple pumping stages, in turn allowing larger size apertures between stages, this way providing very effective ion transmission all the way downstream of the first sampling nozzle.
  • protruding RF ion guides i.e. ion guides that continuously extend between multiple stages
  • the exemplary OA-TOF MS of Fig.1 has the following problems:
  • the fine aperture acts as a distorting lens, and is susceptible to minor side displacements, which requires subsequent ion beam steering;
  • Embodiments of the invention collisionally dampen ions within the RF ion guide and retain the thus achieved small phase space and energy spread of the dampened ion beams all the way through to the final stage of the RF ion guide, through the lens system, and into the orthogonal accelerator.
  • Embodiments of the invention provide: an improved protruding RF ion guide (i.e. an ion guide that extends continuously between multiple stages); a set of optimal parameters (sweet spot) of the protruding RF ion guide; termination of the guide with a wide open aperture; and optimal parameters of ion extraction downstream of the guide.
  • the guide may be coupled to a periodic lens for ease of tuning and for the ability of curving the interface between the ion source and mass analyser.
  • Fig-2 shows an embodiment 200 of an OA-TOF mass spectrometer of the present invention comprising: a front-end interface 30 with an ESI source at atmospheric pressure; a low pressure interface 40; and TOF or MRTOF analyzer 60.
  • Those main components share differentially pumped stages 1 to 6, evacuated by mechanical pumps MP1 and MP2, and by differential ports S3 to S6 of turbo-molecular pump TMP.
  • Interface 30 is exemplified by differential stages 1-3, comprising: an RF ion funnel or tunnel ion guide 31 at pressure P1-10 Torr; an RF funnel, or tunnel, or multipole ion guide 32 at pressure P2 ⁇ l Torr; and an RF quadrupole 33 at pressure P3-0.1 Torr.
  • the diameter of the differential pumping apertures sizes may be: al is from 0.5 to lmm (or a heated 1 mm inner diameter capillary), and a2 ⁇ a3 ⁇ 2mm, which is known to be sufficient for nearly lossless ion transmission all the way downstream of nozzle al.
  • Front end interface 30 may be arranged similar to a variety of prior art front ends, although it is desired that P > ⁇ OmTorr, and that the gas flux Q 4 through aperture a4 remains under lTorr*L/s, for optimal operation of the low pressure interface 40.
  • the gas pressures P1-P6 may be as given in Fig. 2, assuming approximately S4 ⁇ S5 ⁇ S6 ⁇ l00 L/s pumping speeds of differential ports of the split flow turbo-molecular pumps, constructed from (most popular in mass spectrometry) 300L/s turbo-pumps.
  • Interface 40 comprises: a protruding ion guide 41 and periodic lens 51, located within differentially pumped stages 4 and 5.
  • Ion guide 41 is preferably a quadrupole (for stronger ion beam confinement between known RF ion guides) and comprises a set of four rods 42 that are connected to radially sealed and insulating supports 43 and 45, thus forming longitudinal channels 44 and 46 and defining four segments A-D of the otherwise continuous guide.
  • continuous means that the inner bore of the ion guide with diameter D and surrounding features of the guide rods remain constant and non-distorted through the entire guide length.
  • the guide 41 may be aligned with the lens 51 by centering ring 47.
  • the periodic lens 51 comprises; two conductive combs 52, forming alternating potential rings with inner channel 56 of diameter D L , where inner lens diameter is wide D L >2D to reduce lens non-linear effects; slits and slots 53 and 54, serving for electrodes 52 separation and alignment; an aligning support 55; a heater 57 for heating the lens assembly above 150 Celsius; and an exit collimating slit 58.
  • ions are sampled together with gas from gaseous ion source IS through apertures al to a6. Ions are confined radially by RF ion guides 31, 32, 33 and 41, while gas is evacuated via differential pumping ports of mechanical pumps MP1 and MP2 and of multi-stage turbo pump TMP. The gas pressure drops along the interface from 1 atmosphere down to less than lE-8Torr in TOF analyzer at stage 6.
  • Rarified gas flow at Ps ⁇ E-6Torr is already achieved in stage 5, where the ion beam transfer is controlled by fields of periodic lens 51, while the vacuum is strong enough to limit the scattering of ion due to gas collisions to less than 1% of the ions.
  • the embodiment provides a sufficiently high gas pressure at the entrance of the ion guide 41 for collisional ion dampening at the ion guide 41 entrance.
  • the rest of the guide 41 is arranged for non-distorting ion transfer through guide 41, thus delivering a well dampened ion beam into the strong vacuum of P5.
  • ions are extracted into a wide bore of periodic lens 51, in contrast to the fine aperture at the ion guide exit of known instruments. This becomes possible because of the high vacuum at the guide 41 exit.
  • the ion extraction may be optimized at extracting DC fields of less than lV/mm (preferably 0.5V/mm) to form a slowly diverging ion beam.
  • the beam may then be refocused by periodic lens 51 to form a parallel ion beam of a few mm width. Focused and collimated beam 59 enters OA 61.
  • Periodic voltage pulses are applied to OA61 to extract ion packets in the orthogonal (X) direction for mass spectrometric analysis in the TOF analyzer, presented here by the orthogonal accelerator 61, drift space 64, ion mirror 65 and detector 66.
  • equation 300 states an optional goal for the protruding ion guide 41
  • schematic 301 shows ion guide 41 in the XZ-plane
  • view 302 shows a cross section of segment A or C in the XY-plane
  • gas flow model 303 illustrates the efficiency of gas evacuation between the guide rods in segments B and D.
  • Equation 300 set limits onto two gas pressures, i.e. the pressure P A at the entrance part of protruding guide 41, and pressure P D at the guide exit.
  • the relationships provide three features of the protruding ion guide: (a) to dampen the ion beam in a dense gas at P A > ⁇ OmTorr and L A P A >norr*mm (where LA is the length of radially sealed section A of the ion guide), which are known to be sufficient for achieving smallest phase space and energy spread of the ion beam; (b) to preserve the achieved beam parameters all the way to vacuum conditions, which is achieved by continuation of the non-distorted rod geometry through the differential pumping wall of the pumping system; and (c) to reach high vacuum conditions at the guide exit with i3 ⁇ 4 ⁇ lE-6Torr, where ion on gas collisions are practically avoided at the exit of the ion guide and within the subsequent lens system.
  • the a5 aperture diameter of the protruding ion guide shall be under 0.3mm, which does not allow making a non-distorted cross section of the ion guide without strongly compromising the guide acceptance at the entrance part.
  • This problem is solved in the embodiments of the present invention by arranging electrically insulating and longitudinally elongated radial seals 43 and 45, this way splitting the otherwise continuous ion guide into four segments A to D.
  • This provides four features: (i) the longitudinal channel 44 within radial seal 43 at the guide entrance provides for a local rise of gas pressure, since the gas within channel 44 cannot be radially evacuated; (ii) longitudinal channel 46 within radial seal 45 may operate in the free molecular regime at Knudsen number Kn>l, so that the gas conductance of channel 46 becomes suppressed proportionally to the number of channel calibers that the length of the channel corresponds to; and (iii) segments B and D provide for sufficient gas evacuation at moderate elongation if accounting for gas pressure drop along those sections (since segments B and D are not radially sealed and so are able to be radially evacuated).
  • improved shapes of the electrodes may be used to prevent the insulators 43,45 electrically charging within radially sealed channels
  • the guide may comprise four rods 42 with a small inscribed diameter Z ) , selected in the range between 2 and 5mm, and preferably being about 3mm.
  • Radial seals 43 and 45 which may also be used as holders for the electrodes, may be arranged to separate guide 41 into four longitudinal segments A-D with lengths LA-L D of otherwise continuous ion guide 41.
  • the three last segments may be at least ten calibers long, i.e.:
  • gas pressures and parameters of the segments may be chosen to be optimal to provide for:
  • Radial seal 45 is representative for the seal in segments A and C, while rods 42 are representative for all segments of the smooth and non- interrupted ion guide 41.
  • Rods 42 may be split from a single block or tube by electrical discharge machining (EDM), e.g. from stainless steel. Machining may be used for materials with lesser internal stress, e.g. low stress grades of Ti. For better mechanical stability, the rods may use materials like ceramics of aluminium, further chemically coated with electroless nickel.
  • the rods may be arranged such that circumferentially adjacent rods are separated by a narrow gap (e.g.
  • channel 44 (less than a factor of two) and is negligible in channel 46, accounting for free-molecular gas flow regime within long and narrow gaps, where the conductance of slots and gaps is further suppressed at larger number of channel calibers.
  • the entrance channel 44 in segment A is sealed radially, either by insulating holder 43, or by insulating plugs inserted between circumferentially adjacent rod electrodes, or by locally narrowing the gaps h between circumferentially adjacent rod electrodes.
  • the limited conductance of channel 43 provides for a local rise of gas pressure P A at the guide entrance, estimated to be about 30-50 times higher than the pressure at the downstream end of segment B ( P B oP 4 ).
  • the local rise of gas pressure P A may be primarily limited by requirements of the downstream pumping, where the gas flux from the upstream pumping stages may be adopted using flexible parameters of the upfront interface 30.
  • the upstream gas pressure P3 , the entrance aperture conductance a4 and the length of the entrance channel L A of segment A of the ion guide 41 are chosen for sufficient collisional ion dampening, while keeping sufficiently low pressure P 4 , e.g. :
  • the entrance channel of ion guide 41 is formed by protrusion of the guide 41 into the upstream pumping stage 3, this way supporting collisional gas dampening at the entrance of continuous ion guide 41.
  • segment B is shown by an equivalent pumping scheme 303.
  • a long channel with diameter D is continuously evacuated through four side slots having width h. Efficiency of gas evacuation between rods is greatly enhanced because of the axial gas pressure gradient (the effect is similar to efficiency of differential pumping).
  • Axial conductance S A of the guide is proportional to D 2
  • radial conductance through four gaps S R per caliber is proportional to 4hD.
  • Relatively long radial slots, e.g. with H/h> 3 do not affect the radial conductance through the gaps 48, unless gas pressure drops to a few mTorr, i.e. gas flow is in the continuum regime at the slot beginning and in the transition regime downstream.
  • embodiments of the invention propose an improved arrangement of the protruding ion guide with at least two longitudinally extending radial seals, and the following range of "sweet spot" parameters may be used for the protruding RF ion guide 41.
  • the protruding ion guide may have at least four segments A-D.
  • the radial gas seal in segment A (or protrusion into an upstream pumping stage) arranges a local rise of gas pressure, e.g. with P A L A > lTor*mm, accounting for a limited gas conductance along the rods.
  • sufficient gas evacuation is provided, e.g. at length L B /D>10 and gap h>DI 4.
  • a longitudinal channel e.g. at L C ID> 10, may be arranged for the substantial reduction of the channel gas conductance, e.g.
  • gas pressure may be P c ⁇ OmT and Z) ⁇ 5mm for arranging free molecular or transition gas flow at Kn>l.
  • the conductance of channel C may be further reduced to D 3 /L ⁇ 1 mm 2 for ensuring a high vacuum at the guide exit, e.g. with i3 ⁇ 4 ⁇ lE-6Torr.
  • a yet longer channel e.g. L D /D> 20, may be used for sufficient gas evacuation, e.g. at H/h> 3 and h>DI 4.
  • the gas evacuation past segment D may be enhanced by a gap between the guide and the lens and by slots of the lens.
  • the periodic lens may also serve as a long channel suppressing gas flow into the TOF spectrometer.
  • the elongated radial gas seals of the ion guide provide for a substantial drop in gas pressure from a collisional dampening region to high vacuum conditions, while providing for sufficient flexibility in guide parameters.
  • the gas limits in the various segments A-D of the ion guide may be as follows: (i) P A /P D :> 1 E+4; (ii) P B ⁇ lE- 6Torr and RA>1E-2TOGG; and (iii) P B ⁇ lE-6Torr and P A >lTorr/L A (mm), where LA is the length of said first segment.
  • Figs.4A and 4B present results of ion optical simulations of ion extraction from RF ion guide 41 to ion optical system 51.
  • Picture 400 shows ion trajectories at various extraction potentials U E .
  • Energy distributions 405 are compared for high lE-2Torr and low IE- ⁇ Toit pressures at the ion guide exit.
  • Set of plots 406-409 present various ion beam parameters as a function of the normalized extraction potential.
  • ion trajectories 400 are shown for the extraction of lOOOamu ions from a 3mm inner diameter quadrupolar RF ion guide 41, running at an RF frequency of 5MHz and an amplitude of 330V.
  • ions are dampened in gas collisions within an upstream segment (not shown) of the RF ion guide (having the same RF confinement) and are driven at a (typical) lOm/s axial velocity (usually induced by self charge) to the exit portion 401 of the RF ion guide 41, which is located at a high vacuum.
  • the guide 401 is terminated by a shielding aperture 402, also kept at 30V DC.
  • the beam is accelerated downstream to 30eV energy when it enters the grounded entrance section 404 of the lens system 52, and of course, later within the grounded storage region (ion acceptance region) of OA 61.
  • An extraction electrode 403 at variable potential U E is used to control the strength E of the extracting electric field at the exit of exit portion 401, and also to vary the ion beam focusing within two stages of unavoidable ion acceleration: from 401 to 403, and from 403 to 404.
  • the aperture diameter D L may be at least equal to or larger than inscribed diameter of ion guide D, i.e. D L >D, and yet more preferably D L >2D.
  • ETsing a wide aperture eliminates exposure of the aperture walls to stray ions and avoids surface charging. While metal electrodes are considered fully conductive, nevertheless, the metal surfaces are usually coated by residual pumping oil and may be contaminated by electrically insulating sample material. If exposing surfaces to large currents, the charge builds up.
  • the extracting apertures downstream of RF guides appear sensitive to those effects because of the unfavorable combination of: (1) large currents downstream of ion guide 41, e.g.
  • ETsing a wide extraction aperture also solves the problem of non-linear lens effects associated with the small apertures of the prior art, since now the ion beam occupies a small fraction of the aperture opening.
  • use of a wide extraction aperture may result in the voltages used for the downstream acceleration of the ion beam producing strong extraction DC fields E at the RF guide exit.
  • the small energy spread minimizes the ion packets angular divergence in MR-TOF systems, which are described in co-pending applications W02019/030476, WO2019/030477, W02019/030472, W02019/030471 and WO2019/030473.
  • the protruding ion guide 41 described herein may be used with a conventional Einzel lens or telescopic lens, it is preferable to use the periodic lens 51 at least for reasons of: (a) natural optimal ion optical coupling between the guide and the lens, as detailed below; (b) easy adjustments of the periodic lens to compensate for variations of the extracted ion beam, as explained below; (c) easy lens tuning by a single voltage; (d) ease of arranging accurate mutual alignment, here shown with centering ring 47; (e) guaranteed ion beam confinement within periodic lens which eliminates the ion on surface collisions, and (f) ability to bend and twist the overall interface, as described in Fig.7 below.
  • Fig-5 shows a portion 500 of the embodiment 200 shown in Fig. 2 and shows an embodiment of the periodic lens 51 of the present invention.
  • View 501 shows a cross- sectional view along the lens 51.
  • View 502 illustrates another embodiment of the periodic lens, protruding between differentially pumped stages.
  • Periodic lens 51 comprises: two comb electrodes 52, radially separated by slot 53, and having slots 54 for mutual alignment of the comb electrodes 52; heater 57 (e.g. at 150- 200°C); aligning thermal insulator 55 for aligning the lens 51; and a terminating slit 58 through which ions exit.
  • Each comb electrode comprises a plurality of apertured electrodes, such as ring electrodes, that depend from a common spine such that the apertured electrodes are maintained at the same potential in use.
  • the ring electrodes may be attached to a rigid spine or may be integral therewith.
  • the comb electrodes 52 may be made by EDM from a single conductive tube.
  • the ring electrodes in each comb may not be rigidly connected to a spine, but may simply be electrically connected to each other so as to be at the same potential.
  • the two comb electrodes are interleaved such that the apertured electrodes of one comb are arranged between the apertured electrodes of the other comb, and are aligned such that ions are guided longitudinally along the lens 51 through the apertures in the combs.
  • Lens 51 is aligned with rods of guide 41 by an insulating ring 47, which may be ceramic or Vespel.
  • the lens 51 inner diameter D L is chosen larger than the inscribed diameter of the ion guide D, optionally D L ⁇ 2D. Contrary to the prior art, the embodiment does not use any fine apertures between guide 41 and lens 51.
  • the grounded comb 52 of large inner diameter gently extracts ions from the guide 41, e.g. at E ⁇ 0.5V/mm.
  • the exit grounded section of the lens 51 is elongated for minimizing the field strength at the exit aperture 58.
  • the exit slit 58 may function as a differential aperture between stages 5 and 6 of embodiment 200 (Fig. 2), and/or the lens channel 56 itself may act as a differential channel, in particular when using an elongated L L radial seal 55 around the protruding portion of the lens (i.e. the portion extending through aperture between stages 5-6), thanks to suppressed gas conductance of long channels at vacuum and to satisfying Kn»l.
  • the two combs 52 form a set of ring electrodes to which potentials U 1 and U2 are alternately applied, e.g. at spatial period p (i.e. each potential may be applied to electrodes arranged at pitch p).
  • the radially non-uniform field confines ions towards the smaller field gradient, i.e. towards the center of the ring channel.
  • the soft radially confining effective field forms a spatially distributed lens.
  • the ion beam parameters downstream of the lens depend on the initial ion beam parameters, formed at ion extraction from the guide 41.
  • Ion guide 41 is floated at a DC bias voltage U DC , of say 30V, thereby controlling the ion beam energy in the OA.
  • the grounded comb electrode 52 form a gentle extracting field with strength E EX ⁇ U DC /5D L at the exit of RF guide 41.
  • the RF field termination is adiabatic and does not introduce additional angular or energy spread to the ion beam.
  • the guide exit is at vacuum conditions, so there are no ion on gas collisions at ion extraction.
  • the proposed soft ion extraction at vacuum conditions is expected to form ion beams with dKz ⁇ 0AeV energy spread, being drastically different from conventional ion extraction from gas filled ion guides and through fine apertures, where both the simulated and experimentally observed energy spread is dKz ⁇ leV.
  • the lens system operates with a chromatic beam, i.e. does not introduce chromatic aberrations, which helps reduce the angular spread in the beam and, thus, turn around times of ion packets;
  • the OA may use smaller beam energies for higher duty cycles;
  • within the OA-MRTOF of co-pending applications WO2019/030476, WO2019/030477, WO2019/030472, W02019/030471 and W02019/030473 the angular divergence of ion packets is reduced which reduces ion losses in the analyzer and allows an increasing number of mirror reflections for higher MRTOF resolutions.
  • a single potential Ul of periodic lens 51 may be used to control all the processes downstream of the ion guide, such as soft ion extraction, formation of intermediate beam crossover, and formation of a parallel ion beam at the lens exit with a preset magnification of the beam diameter.
  • the system design e.g. manufacturing the periodic lens from a single tube
  • the proposed system provides exceptional ion beam parameters and is easy to tune by a single potential.
  • ion optical simulations of the interface are presented by: set 600 of simulated parameters for the protruding RF ion guide 41 and periodic lens 51; by picture 601 of ion trajectories in the set 600; by graphs 602 and 603 for ion beam parameters in the middle of the orthogonal accelerator obtained using the set 600; and by ion beam emittance in the case of complimenting the set 600 by an extraction system 401 and 402, similar to one used in Fig.4.
  • the presented geometry 600 is strongly expanded in vertical direction for a better view of proportionally expanded ion trajectories in view 601.
  • quadrupolar ion guide 41 has a 3mm inscribed diameter, the guide is floated at a 30V DC mid line bias U DC ⁇ 30V and is fed by an RF signal with 300V zero to peak amplitude at 5MHz frequency, which allows RF stability of lOOamu low mass ions.
  • the gas pressure in the guide is varied from lOmTorr at the upstream ion guide segment (not shown) and down to luTorr at the downstream end (shown). Ions are moved axially by superimposed gas flow at lOm/s velocity, so that they spend at least lms at higher gas pressure for sufficient collisional dampening. Such motion represents typical axial ion propagation, normally induced by a combination of gas flow and self space charge propagation.
  • the overall length of the periodic lens 51 is l33mm.
  • the entrance and exit sections of the lens 51 are formed from grounded rings having lengths of 7mm and 26mm respectively.
  • ions are extracted from ion guide 41 by the ground potential of the entrance ring of the lens 51.
  • Penetration of the extraction field between the ion guide rods forms a weak electrostatic lens with E ⁇ 0.5V/mm at the exit cross section of the guide 41.
  • the combination of a slowly (spatially) decaying RF field and of the extracting DC field forms an intermediate beam crossover 605.
  • the exit ring of the lens 51 is at ground for shielding the lens field at slit 608.
  • a l.4mm high slit 608 trims the beam halo at the entrance of OA 61.
  • graphs 602 and 603 show that the exiting ion beam 608 has a very small angular beam divergence with FWHM 0.3deg and the beam emittance is less than 0.5mm*deg at 30eV energy, both of which are considered to be much superior to the parameters reported in the prior art and measured in experiments.
  • the trimmed beam is highly parallel and travels through the 60mm long OA 61 without any notable spatial spreading.
  • a yet smaller beam divergence FWHM ⁇ 0. l5deg is predicted in simulations, if using an additional extracting system 401 and 402, similar to one used in Fig.4.
  • the extraction system allows flexible adjustments between OA-TOF MS resolution and sensitivity, however, once the optimal compromise if found, a similar reduction of the angular beam divergence and beam spatial magnification may be obtained with optimization of the lens extracting part (say using larger lens diameter).
  • Trajectory picture 601 corresponds to a 50um vertical shift of the ion guide rods. Such accuracy is easy to achieve if using an aligning ring 47 (as in Fig, 4) and the rigid structure of periodic lens 51, described in Fig.5.
  • the 0.05mm radial misalignment tilts the exiting beam by less than 0.05deg, staying well within the beam divergence. The tilt displaces the entire beam across the exit slit 608, and drops ion transmission from 90% to 80%, which is not considered problematic or requiring additional beam steering.
  • the proposed system first, allows precise coaxial alignment between the RF ion guide and periodic lens (by rigidity and alignment of the lens design, so as with use of the aligning ring 47) and, second, is insensitive to minor misalignments at standard manufacturing accuracy. This allows avoiding ion steering elements (typical for prior art lens systems) and the entire lens may be controlled by a single voltage.
  • the simulated beam parameters are notably (three to five times) better than the phase space of experimentally measured ion beams within conventional interfaces, meaning that prior art interfaces were affecting ion beam phase space and axial energy spread.
  • the above description lists multiple possible reasons, such as: ion extraction from the RF guide by a strong field through gas; ion extraction by a strong field through fringing RF fields; extraction via a small size aperture; exposure and charging of a small exit aperture (in particular if the aperture is not heated); non-linear lens effects of the fine aperture; ion on gas scattering within the lens; misalignment of components, where standard optics are highly sensitive to such misalignments.
  • the proposed combination of (a) the improved protruding ion guide with at least two long radial seals, (b) optimal extraction parameters and (c) the periodic lens solves problems associated with prior art interfaces.
  • Both the RF ion guide 41 and periodic lens 51 are characterized by radially confining fields, being axially uniform, effectively forming an ion confining trough.
  • radially confining fields being axially uniform, effectively forming an ion confining trough.
  • a gentle bending of either one or both of the protruding RF ion guide and periodic lens would have moderate or negligible effect on the ion beam parameters.
  • Such an ion path curvature may be used to gain an advantage of compact instrument packaging and would improve protection of the instrument against dust and droplets from the ion source.
  • Fi -7 shows the compact packaging 700 of the ion transfer interface for minimization of the vacuum connections when a turbo-molecular pump cartridge TMP is installed on the axis of the interface, and while the central ion path 603 is arranged to spiral around the TMP.
  • the ion transfer interface may comprise a combination helical ion optical elements 701 and 702, such as the described RF ion guides 41 and periodic lens 51, analytical quadrupoles, CID cells and mobility spectrometers.
  • the helical packaging strongly improves the gas conductance to pumping ports S3, S4 and S5, which in turn allows making the intra-stage gaps and whole TMP notably shorter.
  • Currently produced commercial interfaces for Q-TOF and IMS-TOF instruments are 0.5-lm long.
  • the described embodiments include time-of-flight mass analysers, it is contemplated that other mass analysers (or ion mobility analysers) may be used to benefit from embodiments of the invention.

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Abstract

L'invention concerne une combinaison (200) de guide d'ions RF (41) en saillie et d'une lentille périodique (51) pour un transfert sans distorsion d'ions d'une région d'amortissement de collision efficace dans un accélérateur orthogonal (61) d'un spectromètre de masse à temps de vol multiréfléchissant ou multitour (60). Le système permet une réduction substantielle de l'espace de phase du faisceau d'ions et de l'étalement d'énergie, ce qui permet d'obtenir une combinaison améliorée du temps et de l'étalement d'énergie des paquets d'ions dans le SM à temps de vol. Dans un mode de réalisation (700), l'interface de transfert est disposée en spirale autour d'une pompe turbomoléculaire à ports multiples pour une réduction significative de la longueur d'interface.
PCT/GB2019/052066 2018-07-27 2019-07-24 Interface de transfert d'ions pour sm WO2020021255A1 (fr)

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GB2014485.3A GB2588292B (en) 2018-07-27 2019-07-24 Ion transfer interface for TOF MS

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GB1812329.9 2018-07-27
GBGB1812329.9A GB201812329D0 (en) 2018-07-27 2018-07-27 Improved ion transfer interace for orthogonal TOF MS

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WO2020021255A1 true WO2020021255A1 (fr) 2020-01-30

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US10950425B2 (en) 2016-08-16 2021-03-16 Micromass Uk Limited Mass analyser having extended flight path
US11049712B2 (en) 2017-08-06 2021-06-29 Micromass Uk Limited Fields for multi-reflecting TOF MS
US11081332B2 (en) 2017-08-06 2021-08-03 Micromass Uk Limited Ion guide within pulsed converters
US11205568B2 (en) 2017-08-06 2021-12-21 Micromass Uk Limited Ion injection into multi-pass mass spectrometers
US11211238B2 (en) 2017-08-06 2021-12-28 Micromass Uk Limited Multi-pass mass spectrometer
US11239067B2 (en) 2017-08-06 2022-02-01 Micromass Uk Limited Ion mirror for multi-reflecting mass spectrometers
US11295944B2 (en) 2017-08-06 2022-04-05 Micromass Uk Limited Printed circuit ion mirror with compensation
US11309175B2 (en) 2017-05-05 2022-04-19 Micromass Uk Limited Multi-reflecting time-of-flight mass spectrometers
US11328920B2 (en) 2017-05-26 2022-05-10 Micromass Uk Limited Time of flight mass analyser with spatial focussing
US11342175B2 (en) 2018-05-10 2022-05-24 Micromass Uk Limited Multi-reflecting time of flight mass analyser
US11367608B2 (en) 2018-04-20 2022-06-21 Micromass Uk Limited Gridless ion mirrors with smooth fields
US11587779B2 (en) 2018-06-28 2023-02-21 Micromass Uk Limited Multi-pass mass spectrometer with high duty cycle
US11621156B2 (en) 2018-05-10 2023-04-04 Micromass Uk Limited Multi-reflecting time of flight mass analyser
US11817303B2 (en) 2017-08-06 2023-11-14 Micromass Uk Limited Accelerator for multi-pass mass spectrometers
US11848185B2 (en) 2019-02-01 2023-12-19 Micromass Uk Limited Electrode assembly for mass spectrometer
US11881387B2 (en) 2018-05-24 2024-01-23 Micromass Uk Limited TOF MS detection system with improved dynamic range

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Cited By (17)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10950425B2 (en) 2016-08-16 2021-03-16 Micromass Uk Limited Mass analyser having extended flight path
US11309175B2 (en) 2017-05-05 2022-04-19 Micromass Uk Limited Multi-reflecting time-of-flight mass spectrometers
US11328920B2 (en) 2017-05-26 2022-05-10 Micromass Uk Limited Time of flight mass analyser with spatial focussing
US11211238B2 (en) 2017-08-06 2021-12-28 Micromass Uk Limited Multi-pass mass spectrometer
US11756782B2 (en) 2017-08-06 2023-09-12 Micromass Uk Limited Ion mirror for multi-reflecting mass spectrometers
US11239067B2 (en) 2017-08-06 2022-02-01 Micromass Uk Limited Ion mirror for multi-reflecting mass spectrometers
US11295944B2 (en) 2017-08-06 2022-04-05 Micromass Uk Limited Printed circuit ion mirror with compensation
US11081332B2 (en) 2017-08-06 2021-08-03 Micromass Uk Limited Ion guide within pulsed converters
US11049712B2 (en) 2017-08-06 2021-06-29 Micromass Uk Limited Fields for multi-reflecting TOF MS
US11817303B2 (en) 2017-08-06 2023-11-14 Micromass Uk Limited Accelerator for multi-pass mass spectrometers
US11205568B2 (en) 2017-08-06 2021-12-21 Micromass Uk Limited Ion injection into multi-pass mass spectrometers
US11367608B2 (en) 2018-04-20 2022-06-21 Micromass Uk Limited Gridless ion mirrors with smooth fields
US11621156B2 (en) 2018-05-10 2023-04-04 Micromass Uk Limited Multi-reflecting time of flight mass analyser
US11342175B2 (en) 2018-05-10 2022-05-24 Micromass Uk Limited Multi-reflecting time of flight mass analyser
US11881387B2 (en) 2018-05-24 2024-01-23 Micromass Uk Limited TOF MS detection system with improved dynamic range
US11587779B2 (en) 2018-06-28 2023-02-21 Micromass Uk Limited Multi-pass mass spectrometer with high duty cycle
US11848185B2 (en) 2019-02-01 2023-12-19 Micromass Uk Limited Electrode assembly for mass spectrometer

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GB2588292A (en) 2021-04-21

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