Efficient Ion Trapping

Abstract

An ion trapping system is disclosed comprising an ion urging system for urging ions to spread out within an ion trapping region. Alternatively, the ion trapping system may deflect ions such that ions enter the ion trapping region at different locations. Alternatively, an ion deflector may be arranged upstream of, or at the entrance to, the ion trapping region, for deflecting ions such that ions enter the ion trapping region with different speeds so that the ions spread out within the ion trapping region.

Claims

1. An ion trapping system comprising: a plurality of electrodes; one or more voltage supplies connected to the electrodes, wherein the electrodes and the one or more voltage supplies are adapted and configured to provide an ion trapping region in use; an ion entrance for receiving ions into the ion trapping region along an ion entrance axis, in use; an ion ejecting system for ejecting ions from the ion trapping region along an ion exit axis in use, wherein the electrodes and voltage supplies are configured such that the maximum dimension over which the ion trapping region extends orthogonal to the entrance axis and/or exit axis is greater than the maximum dimension over which the ion trapping region extends parallel to the entrance axis and/or exit axis; and further comprising one or more of the following: (i) an ion urging system for urging ions within the ion trapping region orthogonally to the entrance and/or exit axis so that the ions spread out within the ion trapping region, wherein the ion trapping region is adapted and configured to be maintained at a pressure of ≧0.01 mbar; and/or (ii) an ion deflector arranged upstream of the ion trapping region, wherein the ion deflector is configured to deflect at least some of the ions travelling towards the ion trapping region such that ions entering the ion trapping region enter the ion trapping region at different locations; and/or (iii) an ion deflector arranged upstream of, or at the entrance to, the ion trapping region, wherein the ion deflector is configured to deflect at least some of the ions travelling towards or into the ion trapping region such that ions enter the ion trapping region with different speeds orthogonal to the exit axis and/or the entrance axis so that the ions spread out within the ion trapping region in a direction orthogonal to the entrance axis and/or exit axis.

2. The system of claim 1, comprising a controller and electronic circuitry arranged and configured to: control the one or more voltage supplies so as to apply voltages to the electrodes such that ions are able to be received into the ion trapping region along said entrance axis and trapped in the ion trapping region during an ion filling period; and wherein the controller is arranged and configured to: (i) control the ion urging system to urge ions to spread out within the ion trapping region orthogonally to the entrance and/or exit axis during the ion filling period; and/or (ii) control the ion deflector to deflect at least some of the ions travelling towards the ion trapping region such that ions entering the ion trapping region enter the ion trapping region at different locations during the ion filling period; and/or (iii) control the ion deflector to deflect at least some of the ions travelling towards or into the ion trapping region such that ions enter the ion trapping region with different speeds orthogonal to the exit axis and/or the entrance axis during the ion filling period so that the ions spread out within the ion trapping region in a direction orthogonal to the entrance axis and/or exit axis.

3. The system of claim 1, wherein the ion urging system is arranged and configured to urge the ions to spread out within the ion trapping region in a dimension substantially corresponding to the maximum dimension of the ion trapping region.

4. The system of claim 1, wherein the ion urging system is adapted and configured to apply a potential gradient, optionally a DC potential gradient, across the ion trapping region for causing said ions to spread out orthogonally to the entrance axis and/or exit axis; and/or wherein the ion urging system is adapted and configured to translate at least one transient DC voltage along the ion trapping region for causing said ions to spread out orthogonally to the entrance axis and/or exit axis; and/or wherein the ion urging system comprises a gas pump adapted and configured to create a gas flow for causing said ions to spread out orthogonally to the entrance axis and/or exit axis.

5. The system of claim 1, wherein the ion deflector is configured to deflect ions travelling towards the ion trapping region such that ions entering the ion trapping region either (i) at the same time, or (ii) at different times, enter the ion trapping region at different locations; optionally wherein the ion deflector is configured to deflect ions by varying the mean axis along which ions enter the ion trapping region with time, or by defocussing, diverging, splitting or otherwise spreading out at least some of the ions in an ion beam or ion packet.

6. The system of claim 1, wherein the ion deflector comprises at least one electrode and at least one voltage supply adapted and configured to apply a time varying electrical potential to the at least one electrode for performing the step of deflecting the ions.

7. The system of claim 1, wherein the ion deflector comprises an inverted ion funnel arranged upstream of the ion trapping region, the inverted ion funnel comprising at least one inner electrode and at least one outer electrode surrounding the at least one inner electrode and defining an ion guiding path therebetween, wherein the ion guiding path has a cross-sectional area that increases in a direction towards the ion trapping region.

8. The system of claim 7, wherein the ion deflector is configured to cause ions to spiral around the at least one inner electrode as they travel towards the ion trapping region; or wherein the ion deflector is configured to cause ions to travel in an axial direction along the ion funnel, substantially without spiralling around the at least one inner electrode, and such that the ions entering the inverted ion funnel at different times travel along different axial ion paths.

9. The system of claim 1, wherein the ion deflector comprises at least one electrode arranged radially spaced from an ion beam axis and at least one voltage supply configured to apply at least one voltage to this at least one electrode so as to simultaneously urge ions in multiple directions orthogonal to the ion beam axis; optionally wherein the at least one electrode at least partially surrounds the ion beam axis.

10. The system of claim 9, wherein the at least one electrode comprises a plurality of electrodes arranged at different radial distances from the ion beam axis, and wherein the at least one voltage supply is configured to apply DC potentials to these electrodes so as to generate a static DC potential gradient in the radially outward direction or a travelling DC potential barrier that travels in the radially outward direction for simultaneously urging ions in multiple directions orthogonal to the ion beam axis.

11. The system of claim 9, wherein the ion deflector comprises an ion blocking electrode arranged downstream of said at least one electrode on the ion beam axis and a voltage supply for applying a voltage to the ion blocking electrode to repel ions away from it, optionally such that the ion blocking electrode and the at least one electrode cooperate to simultaneously urge ions in multiple directions orthogonal to the ion beam axis.

12. A mass and/or ion mobility spectrometer comprising an ion trapping system as claimed in claim 1 and an ion receiving device arranged downstream of the ion trapping system for receiving ions from the exit of the ion trapping system.

13. The spectrometer of claim 12, comprising a controller, a voltage supply and circuitry arranged and configured to pulse ions out of the ion trapping region and into the ion receiving device.

14. The spectrometer of claim 12, wherein the ion receiving device is an ion separation device arranged for receiving ions from the exit of the ion trapping region and separating these ions according to a physicochemical property; and/or wherein the ion receiving device is adapted and configured to receive ions through an entrance gate that is opened and closed over time, optionally wherein the opening of the gate is synchronised with one or more periods over which ions are ejected from the ion trapping region.

15. The spectrometer of claim 14, wherein the ion separation device is configured to separate the ions according to said physicochemical property along an ion separation axis that is parallel and/or coaxial with said exit axis of the ion trapping region; optionally wherein the separation device is an ion mobility separator and the physicochemical property is ion mobility.

16. The system of claim 1, wherein said ion trapping region and/or ion receiving device are configured to be maintained at a pressure selected from the group consisting of: ≧1×10.sup.−2 mbar; ≧5×10.sup.−2 mbar; ≧0.1 mbar; ≧0.5 mbar; ≧1 mbar; ≧5 mbar; ≧10 mbar; ≧15 mbar; ≧20 mbar; ≧30 mbar; ≧40 mbar; ≧50 mbar; ≧100 mbar; ≧250 mbar; and ≧50 mbar.

17. An ion trapping system comprising: a plurality of electrodes; one or more voltage supplies connected to the electrodes, wherein the electrodes and the one or more voltage supplies are adapted and configured to provide an ion trapping region in use; an ion entrance for receiving ions into one end of the ion trapping region and an ion exit for ejecting ions from another end of the ion trapping region, in use; an ion urging system adapted and configured to translate at least one transient DC voltage along the ion trapping region from the ion entrance to the ion exit for urging along the ion trapping region, wherein the ion urging device is adapted and configured to control the transient DC voltage so that the force it applies to the ions towards the exit decreases as the transient DC voltage travels towards the exit; and a control system adapted and configured to control the one or more voltage supplies to apply one or more voltages to the electrodes to prevent ions being ejected from the ion trapping region by the at least one transient DC voltage when the transient DC voltage reaches the ion exit.

18. The system of claim 17, wherein the amplitude of the transient DC voltage decreases, progressively decreases or decays as is travels from the ion entrance to the ion exit.

19. The system of claim 17, wherein the controller is arranged and configured to: control the one or more voltage supplies so as to apply voltages to the electrodes such that ions are able to be received into the ion trapping region through the ion entrance and trapped in the ion trapping region during an ion filling period; and to control the ion urging system so that the transient DC voltage transient DC voltage travels along the ion trapping region during the ion filling period.

20. A method of trapping ions comprising: providing an ion trapping system as claimed in claim 1; applying voltages to the plurality of electrodes so as to provide the ion trapping region; receiving ions into the ion trapping region along the ion entrance axis and preventing ions exiting the ion trapping region, whilst performing one or more of the following: (i) using the ion urging system to urge ions within the ion trapping region orthogonally to the entrance and/or exit axis so that the ions spread out within the ion trapping region; and/or (ii) using the ion deflector to deflect ions travelling towards the ion trapping region such that ions entering the ion trapping region enter the ion trapping region at different locations; and/or (iii) using the ion deflector to deflect ions travelling towards or into the ion trapping region such that ions enter the ion trapping region with different speeds orthogonal to the exit axis and/or the entrance axis so that the ions spread out within the ion trapping region in a direction orthogonal to the entrance axis and/or exit axis.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0142] Various embodiments will now be described, by way of example only, and with reference to the accompanying drawings in which:

[0143] FIG. 1 shows a schematic of a prior art stacked ring ion guide having an ion trapping region;

[0144] FIG. 2 shows an example of the geometry of an ion trap that may be used in accordance with the present invention;

[0145] FIG. 3 shows a SIMION model of how an ion population is distributed within an extended trapping region during the trap fill cycle;

[0146] FIG. 4 shows similar plots to those shown in FIG. 3, except for various different ion trapping pressures;

[0147] FIG. 5 shows similar plots to those shown in FIG. 3, except for four different ion fill rates;

[0148] FIG. 6 shows the peak charge density in an ion trap as a function of the total spread of ions in a dimension of the ion trap;

[0149] FIG. 7 shows plots of the effective temperatures as functions of mass to charge ratio for four different peak charge densities in the trap configuration of FIG. 2;

[0150] FIG. 8 shows an embodiment of the present invention having an annular ion confinement volume;

[0151] FIG. 9 shows another embodiment of the present invention having an annular inverted ion funnel around which ions spiral, and an annular ion trapping region;

[0152] FIG. 10 shows another embodiment of the present invention that is structurally similar to that shown in FIG. 9, except that the ions are not spiralled around the ion funnel;

[0153] FIG. 11 shows another embodiment of the present invention comprising an orthogonal ion distribution region and an annular ion trapping region;

[0154] FIGS. 12A and 12B show schematics of an ion deflector being operated in different modes;

[0155] FIG. 13 shows a schematic of an ion deflector being operated in yet another mode; and

[0156] FIGS. 14A-14C show other embodiments of the invention, wherein ions are driven along the longitudinal axis of an elongated ion trapping region.

DETAILED DESCRIPTION

[0157] FIG. 1 shows a schematic of a prior art stacked ring ion guide 1 having an ion trapping region. The ion guide is formed from a plurality of apertured electrodes having their apertures aligned so as to form an ion guiding channel through the ion guide. Opposite phases of a radio frequency AC voltage are applied to adjacent ring electrodes so as to form an RF pseudo-potential well that radially confines ions within the ion guide. An axial DC potential well is formed in the ion guide by application of appropriate DC potentials to the electrodes in the ion guide. The solid line in the lower plot of FIG. 1 shows the DC voltages applied to the electrodes as a function of the distance L along the ion guide. It can be seen that the same DC voltages are applied to the electrodes at the ends of the ion guide, but that a lower DC voltage is applied to a subset of the electrodes between the ends of the ion guide. The dotted line in the lower plot of FIG. 1 shows the DC potential profile arranged along the ion guide as a result of the DC voltages applied to the electrodes. As can be seen, a DC well is generated that confines ions to a narrow trapping region of the ion guide.

[0158] The ion guide may be coupled to an ion mobility separation (IMS) device in order to improve the duty cycle of the instrument. For example, ions may be accumulated in the trapping region of the ion guide from an upstream source of ions and then pulsed into the IMS device. Whilst the ions are separating in the IMS device it may be undesirable to permit further ions to enter the IMS device. During this period, ions from the upstream ion source are accumulated in the trapping region of the ion guide, such that they are not lost and so that the duty cycle of the instrument is improved. These ions may subsequently be pulsed into the IMS device. Ions may therefore be accumulated in the trapping region and periodically released into the downstream ion mobility separation region at the start of each IMS separation cycle.

[0159] However, the ion trapping region shown in FIG. 1 has a relatively low ion trapping volume and hence has a relatively low space-charge capacity. In order to provide a relatively large ion trapping volume, so as to minimize local charge density, the dimensions of the ion trapping region may be extended in one or more dimensions. However, if the ion trapping volume is extended in the same direction as the direction of ion mobility separation in the IMS device, then the ions must be refocused in the direction of ion mobility separation prior to the ion mobility separation in order to maintain a high resolution for ion mobility measurements. On the other hand, if the ion trapping region is extended in a direction orthogonal to the direction of ion separation in the IMS device, then the ion cloud trapped in the ion trapping region would have minimal spatial spread in the direction of ion mobility separation. This would allow rapid and efficient transfer of ions from the ion trapping region into the ion separation region, because it minimizes or negates the requirement to refocus the ions in the direction of ion mobility separation prior to pulsing the ions into the IMS device.

[0160] FIG. 2 shows an example of the geometry of an ion trap that has been extended in an attempt to reduce space-charge effects. The ion trap comprises an upper array of parallel plate electrodes 2 that is spaced apart from a corresponding lower array of parallel plate electrodes so as to form an ion guiding region between the arrays. The plate electrodes are arranged such that their planes extend in the direction from the upper array to the lower array. A side plate electrode 3 is arranged at each side of the ion trap so as to extend between the upper and lower arrays. Each side plate electrode 3 has its plane orthogonal to the planes of the plate electrodes 2 in the upper and lower arrays. Ions are able to be confined between the upper and lower arrays of electrodes in the y-dimension by applying opposite phases of an RF voltage to electrodes plates 2 that are adjacent to each other in the z-dimension. Ions are able to be confined in the x-dimension by applying DC voltages to the side plates electrodes 3. Ions may be trapped in the z-dimension by applying different DC voltages to plate electrodes 2 in the upper and/or lower arrays so as to form a DC potential well that extends in the x-dimension. The size of the ion trapping region in the x-dimension may extend over a relatively large distance so as to provide a relatively large ion trapping volume. The plates electrodes 2 may be curved to form an arcuate ion trapping region.

[0161] As shown on FIG. 2, ions enter the ion trapping region along the z-axis and over a fixed period of time and as a continuous stream of ions 4. The incident ion beam has a cross-section smaller than the dimensions of the ion trapping region. Without any active driving of ions within the ion trapping region, the volume occupied by ions during the ion trap filling is related to the rate of diffusion of the ions in the gas within the trapping region, the initial kinetic energy of the ions, the mobility of the ions and the driving force experienced by the ions due to space-charge interactions within the trapped ion cloud.

[0162] FIG. 3 shows a SIMION model of how an ion population is distributed within an extended trapping region during the trap fill cycle. The model is based on the arrangement shown in FIG. 2, wherein the plate electrodes 2 are considered to have a thickness of 0.5 mm, the spacing in the z-dimension between the plate electrodes 2 is considered to be 1 mm, and the ion confining region between the plate electrodes 2 in the y-dimension is considered to be 5 mm. The RF voltage applied to the plate electrodes 2 for confining ions in the y-dimension was modeled as having an amplitude of 125 V (0-peak) and a frequency of 2.5 MHz, with opposite phases applied to adjacent electrodes 2. Positive ion trapping was modeled. Ion trapping in the z-dimension was modeled by applying the same DC voltage to all of the plate electrodes 2 in the arrays, except for 8 consecutive plate electrodes 2 in the z-dimension, which were maintained at a DC voltage 20 V lower than the other plate electrodes 2. The dimension of the device in the x-dimension was modeled as not being restrained, so that the natural distribution of ions in this direction could be examined under differing conditions. The gas within the device was modeled as being nitrogen at 2.5 Torr. Ions having a mass to charge ratio of 500 were simulated as being created in the centre of the ion trapping region every 20 μs. The ions were simulated as carrying 20,000 charges, thus giving an average rate of 1000 charges per μs.

[0163] In FIG. 3, the Y-ordinate represents the number of charges per mm in the x-dimension and the X-ordinate represents the position along the x-axis in the ion trap (in mm), with 0 mm representing the central position along the x-axis of the ion trap. FIG. 3 shows three plots, representing the distribution of ions in the ion trap after ion filling durations of 1 ms (inner plot), 5 ms (middle plot) and 10 ms (outer plot). The plots in FIG. 3 show that ions fill more and more of the ion trapping volume as the ion accumulation time increases, due to increasing space-charge repulsion effects. However, it can also be seen that the maximum charge density, which occurs where the continuous ion beam enters the trapping region, continues to increase as the length of the trapping period increases. Therefore, under these conditions, this local region of the ion trapping volume fills at a faster rate than the space-charge repulsion drives ions out of this region to fill the ion trapping volume. The local charge density in this region therefore increases and ions may dissociate or become unstable due to interaction with the RF radial confining fields. For instance, in this example, at an ion fill time of 10 ms the ions have only become distributed over approximately 60 mm of the ion trapping volume (along the x-axis), regardless of how large the ion trapping volume is made in the x-dimension.

[0164] FIG. 4 shows the same plot as in FIG. 3 for an ion filling duration of 10 ms and an ion trapping pressure of 2.5 Torr (uppermost plot). However, FIG. 4 also shows ion distributions after an ion filling duration of 10 ms for ion trapping pressures of 1 Torr (middle plot) and 0.2 Torr (lowermost plot). It can be seen from FIG. 4 that at 10 ms ions are distributed over a larger volume of the ion trap (in the x-dimension of the trap) when the trapping volume is maintained at a lower pressure. The peak charge density in the ion trapping region is therefore reduced at lower ion trapping pressures. Accordingly, when ion traps are operated at higher pressures, e.g. to couple them with drift time IMS devices, ions take longer to become distributed throughout the ion trapping volume and hence the peak charge density is relatively high.

[0165] FIG. 5 shows similar plots to those shown in FIG. 3, except for four different ion fill rates. FIG. 5 shows the ion distributions in the trap for the four ion fill rates at an ion filling duration of 10 ms and for an ion trapping pressure of 2.5 Torr of Nitrogen. The total number of charges introduced into the ion trapping region, the peak charge density at 10 ms and the spread of ions in the x-dimension of the ion trap after 10 ms are shown in the table below for the four different ion fill rates. The plots in FIG. 5 have been scaled in intensity so that the differences in the spreads of the ions in the X-direction of the ion trap can be seen more easily.

TABLE-US-00001 Fill rate Total no. Peak charge density Ion spread (charges/μs) charges (mm.sup.−1) (mm) 100 1 × 10.sup.6  6.5 × 10.sup.4 34 mm 1000 1 × 10.sup.7 2.85 × 10.sup.5 68 mm 10000 1 × 10.sup.8 1.16 × 10.sup.6 168 mm 100000 1 × 10.sup.9 5.37 × 10.sup.6 320 mm
The total number of charges introduced into the ion trapping region, the peak charge density and the spread of ions in the x-dimension of the ion trap increase with ion filling rate.

[0166] FIG. 6 plots the peak charge density (charges/mm) in the ion trap of FIG. 5 as a function of the total spread of ions in the x-dimension of the ion trap (in mm). From this plot it is clear that as the input flux of ions increases the maximum charge density increases, and at a rate faster than the increasing space-charge effects can drive ions to fill the available trapping volume.

[0167] As described above, high charge densities may cause heating of the ions. In order to estimate the heating effect of the peak charge densities in the ion trap configuration of FIG. 2, SIMION was used to model this effect using uniform charge density distributions corresponding to peak charge densities. Trajectories were then modeled for ions in the fields derived from these distributions and average kinetic energies, and hence effective temperatures, were recorded. The effective temperatures were calculated according to the method described in TOLMACHEV ET AL, J Am Soc Mass Spectrom 2004, 15, 1616-1628.

[0168] FIG. 7 shows plots of the effective temperatures as functions of mass to charge ratio for four different peak charge densities in the trap configuration of FIG. 2. The four charge peak charge densities are: A=7.13×10.sup.4 charges mm.sup.−1, B=2.85×10.sup.5 charges mm.sup.−1, C=5.34×10.sup.5 charges mm.sup.−1, and D=7.13×10.sup.5 charges mm.sup.−1. FIG. 7 shows that an increase in the peak charge density within the ion trap leads to a higher effective temperature, due to interaction between the ions and the RF confining field. This temperature increase can lead to ion losses due to dissociation of the ions.

[0169] It is also recognized that the peak charge density is related to the mobility of the ions. Low mobility ions will spread within the ion trap less than high mobility ions for the same ion fill rate and so the peak charge will be greater for low mobility ion species. Also, multiply charged ions of similar mass to charge ratio to ions of a lower charge state will spread within the trapping volume more rapidly and hence peak charge will be lower for the same fill rate. In practice, the incoming ion beam will be composed of ion species with a range of different mobilities, masses and charge states.

[0170] According to embodiments of the present invention, the local charge density within an ion trap is minimized by actively driving ions within the ion trapping region, or external to the ion trapping region, so that the ions become more evenly distributed within the ion trapping volume relatively quickly. This addressed adverse effects that would otherwise be cause by space-charge effects within the ion trap and within the IMS device.

[0171] FIG. 8 shows an embodiment of the invention. The ion trap comprises an array of inner electrodes 6 and an array of outer electrodes 5 that define an annular ion confinement region therebetween. FIG. 8 only shows part of the array of outer electrodes 5, in order that the ion path can be seen more easily, although it will be appreciated that the outer array may extend fully around the circumference of the array of inner electrodes 6. RF voltages are applied to the arrays of electrodes 5,6 for confining ions in the annular space therebetween. More specifically, each array comprises a plurality of electrodes arranged along the longitudinal axis of the device and opposite phases of an RF voltage may be supplied to longitudinally adjacent electrodes in each array so as to radially confine the ions between the inner and outer arrays of electrodes. Different DC voltages are applied to the different electrodes along the axis of the device so as to define an axial DC trapping potential well that traps ions along the axis. In the illustrated embodiment, the axial trapping potential is a DC quadratic potential well. The device therefore defines an ion trapping volume for trapping the ions. Each of the inner array 6 and outer array 5 comprises a plurality of electrodes spaced circumferentially around the longitudinal axis for use as described further below.

[0172] In use, a beam of ions is directed into the ion trap along the longitudinal axis of the trap. Alternatively, the ions may enter the trap tangentially to the annular region, i.e. orthogonal to the longitudinal axis. A DC potential is successively applied to different ones of the electrodes that are spaced circumferentially around the longitudinal axis of the device, so as to drive the ions circumferentially around the annular region as they enter the ion trapping region. This driving force urges the ions away from the point of entry of the ion beam within the trapping region and distributes ions around the trapping volume.

[0173] Ions of high mobility will be driven with a higher velocity around the annular volume compared to ions with lower mobility. The annular design of the ion trap allows ions of high mobility to be driven circumferentially around the ion trapping volume multiple times, allowing ions of lower mobility to be distributed effectively and for the charge density at any local region to be minimized. This is in contrast to other ion trap configurations, such as that shown in FIG. 2, wherein the application of a driving force in the x-direction may concentrate ions of high mobility close to side plate electrodes 3 and hence may cause an increase in charge density.

[0174] FIG. 9 shows another embodiment of the present invention which may be used to efficiently fill an annular trapping volume. The device comprises a ion injection section, an annular inverted ion funnel 7 and an annular ion trapping region 8. The ion injection section forms an ion guide for guiding ions into the inverted ion funnel section 7. The inverted ion funnel section comprises an array of inner electrodes and an array of outer electrodes that define an annular ion confinement region therebetween, in a similar manner to the device of FIG. 8 except that the annular region has a progressively larger radius along the device in a direction from the entrance to the exit of the device. RF voltages are applied to the arrays of electrodes for confining ions in the annular space therebetween. Each array may comprise a plurality of electrodes arranged along the longitudinal axis of the device and opposite phases of an RF voltage may be supplied to longitudinally adjacent electrodes in each array so as to radially confine the ions between the inner and outer arrays of electrodes. Different DC voltages may be applied to different electrodes along the axis of the device so as to define an axial DC potential that urges ions along the axis to the ion trapping region 8. Each of the inner array and outer array of electrodes may comprise a plurality of electrodes spaced circumferentially around the longitudinal axis for use as described further below.

[0175] In use, a beam of ions is directed into the ion trap along the longitudinal axis of the trap. Alternatively, the ions may enter the trap tangentially to the annular region, i.e. orthogonal to the longitudinal axis. The ions then pass into the inverted ion funnel section 7. A DC potential is successively applied to different ones of the electrodes that are spaced circumferentially around the longitudinal axis of the inverted ion funnel section 7, so as to drive the ions circumferentially around the annular region as they enter the inverted ion funnel section 7. This driving force urges the ions away from the point of entry of the ion beam within the inverted ion funnel section 7 and circulates the ions around the annular region. The ions then pass into the annular ion trapping region 8, which comprises an array of inner electrodes and an array of outer electrodes that define an annular ion confinement region therebetween. RF voltages are applied to the arrays of electrodes for radially confining ions in the annular space therebetween. Each array may comprise a plurality of electrodes arranged along the longitudinal axis of the device and opposite phases of an RF voltage may be supplied to longitudinally adjacent electrodes in each array so as to radially confine the ions between the inner and outer arrays of electrodes. Different DC voltages may be applied to different electrodes along the axis of the device so as to define an axial DC potential for axially trapping ions along the axis of the ion trapping region 8. Once the ions enter the annular ion trapping region 8 from the inverted ion funnel 7, the ions continue to rotate around the longitudinal axis of the device, thereby distributing the charge density within the ion trapping region 8 in a similar manner to the embodiment in FIG. 8.

[0176] FIG. 10 shows another embodiment of the present invention that is structurally similar to that shown in FIG. 9, except that the inner and outer arrays of electrodes need not (although may) comprise electrodes spaced circumferentially around the longitudinal axis for use in rotating the ions around the longitudinal axis. Rather, in the embodiment of FIG. 10, the continuous ion beam is deflected in a circular motion by a segmented deflection electrode as the continuous beam enters the inverted funnel region. More specifically, the ion beam travels substantially parallel to the longitudinal axis of the device prior to entering the device. Deflection electrodes then deflect the ions away from this axis as, or prior to, the ions entering the device. The ions are deflected in a direction orthogonal to the axis, but maintain a component of velocity along the axis such that the ions continue into the inverted ion funnel section. Although the ions are always deflected orthogonal to the axis, the orthogonal direction in which the ions are deflected varies with time such that ions entering the device at different times travel along different paths through the inverted funnel section and arrive at different regions of the annular trapping region. The orthogonal direction in which the ions are deflected may rotate around the longitudinal axis with time, either continuously or in a stepped manner. The orthogonal direction in which the ions are deflected may rotate around the longitudinal axis at least once during the fill time of the ion trap. The orthogonal deflection may be achieved by providing deflection electrodes around the axis and energising these electrodes at different times such that the orthogonal direction in which the ions are deflected varies with time. The embodiment of FIG. 10 is able to distribute ions around the annular trapping volume in a manner that is largely independent of the mobility of the ions.

[0177] FIG. 11 shows another embodiment of the present invention. This embodiment comprises the sequential arrangement of an ion tunnel ion guide 12, an orthogonal ion distribution region 9 and an annular ion trapping region 8. An ion deflector 10 may be provided between the ion tunnel ion guide and the orthogonal ion distribution region 9. The ion tunnel ion guide comprises a plurality of apertured electrodes. The orthogonal ion distribution region 9 may comprise a first member 14 having a aperture therein and arranged at the longitudinal axis for allowing ions to pass therethrough. The first member of the orthogonal ion distribution region 9 also comprises a plurality of electrodes arranged concentrically around the aperture at different radial distances from the aperture. The orthogonal ion distribution region 9 comprises a second member 16 downstream of the first member. The second member comprises an inner electrode and an outer electrode that define an annular aperture therebetween for allowing ions to pass therethrough. The ion trapping region is arranged downstream of the orthogonal ion distribution region 9. The ion trapping region comprises an array of inner electrodes and an array of outer electrodes that define an annular ion confinement region therebetween.

[0178] In use, RF voltages are applied to the electrodes of the ion tunnel ion guide 12 so as to radially confine ions within the ion guide along the longitudinal axis of the device. Opposite phases of an RF voltage may be applied to longitudinally adjacent electrodes in the ion guide so as to radially confine the ions. The ions travel axially along the ion guide and through the aperture in the first member of the orthogonal ion distribution region 9. The ions pass into the region axially between the first and second members of the orthogonal ion distribution region 9. RF voltages are applied to the concentric electrodes of the first member 14 and an RF or DC voltage is applied to at least the central electrode of the second member 16 so that ions are repelled away from these members and hence confined axially between the first and second members. The central electrode of the second member 16 therefore acts as an ion blocking electrode that repels ions away from it. Different DC voltages are applied to the concentric electrodes on the first member of the orthogonal ion distribution region 9 so as to create a DC gradient that drives the ions radially outward and towards the annular aperture in the second member 16 of the orthogonal ion distribution region 9. Alternatively, a DC potential may be successively applied to successive concentric electrodes on the first member such that the ions are driven radially outward towards the annular aperture in the second member of the orthogonal ion distribution region 9. The DC potential may be repeatedly travelled along the concentric electrodes in this manner. The orthogonal ion distribution region 9 may therefore be operated to distribute ions evenly around an annulus within the device.

[0179] Electric potentials are applied to the first member 14 and/or second member 16 and/or ion trapping region 8 so as to urge the ions through the annular aperture in the second member of the orthogonal ion distribution region 9 and into the ion trapping region 8. RF voltages are applied to the arrays of electrodes in the ion trapping region 8 for confining ions in the annular space therebetween. More specifically, each array may comprises a plurality of electrodes arranged along the longitudinal axis of the device and opposite phases of an RF voltage may be supplied to longitudinally adjacent electrodes in each array so as to radially confine the ions between the inner and outer arrays of electrodes. Different DC voltages are applied to the different electrodes along the axis of the device so as to define an axial DC trapping potential well that traps ions along the axis. The axial trapping potential may be a DC quadratic potential well. The orthogonal ion distribution region 9 therefore enables the ion trapping region 8 to be filled with ions such that the ions are distributed substantially evenly around an annulus within the ion trapping region.

[0180] As mentioned above, an ion deflector 10 may be provided between the ion tunnel ion guide 12 and the orthogonal ion distribution region 9. Embodiments of the ion deflector are shown in FIGS. 12A and 12B.

[0181] FIG. 12A shows a schematic representation of the DC potential surface and ion trajectories within the orthogonal ion distribution region 9. This demonstrates that the orthogonal ion distribution region 9 drives the ions radially outwards and through the annular aperture in the second member 16 of the orthogonal ion distribution region 9. FIG. 12A also shows the ion deflector 10 that may be provided between the ion tunnel ion guide and the orthogonal ion distribution region 9. The ion deflector 10 may be a segmented deflection electrode for deflecting the ion beam in a circular motion as the beam enters the orthogonal ion distribution region 9. More specifically, the ion beam travels substantially parallel to the longitudinal axis of the device prior to entering the ion deflector. Electrodes of the ion deflector 10 then deflect the ions away from this axis. The ions are deflected in a direction orthogonal to the axis, but maintain a component of velocity along the axis such that the ions continue into the orthogonal ion distribution region 9. Although the ions are always deflected orthogonal to the axis, the orthogonal direction in which the ions are deflected varies with time such that ions entering the ion deflector at different times travel along different paths through the orthogonal ion distribution region 9 and arrive at different regions of the annular trapping region. The orthogonal direction in which the ions are deflected may rotate around the longitudinal axis with time, either continuously or in a stepped manner. The orthogonal direction in which the ions are deflected may rotate around the longitudinal axis at least once during the fill time of the ion trap. The orthogonal deflection may be achieved by providing deflection electrodes around the axis and energising these electrodes at different times such that the orthogonal direction in which the ions are deflected varies with time.

[0182] FIG. 12B shows a mode in which the ion deflector 10 is operated so as to distribute ions over only part of the trapping region. In this mode the voltages applied to the electrodes of the ion deflector are varied with time such that ions are only deflected along a single axis orthogonal to the longitudinal axis. For example, voltages may be applied to the ion deflector so as to scan ions in a single dimension orthogonal to the longitudinal axis. These ions then enter the orthogonal ion distribution region 9 and are forced radially outward, thereby filling a semi-circular region of the annular ion trapping region.

[0183] Although various annular ion trapping regions have been described, the present invention is not limited to annular trapping regions. For example, an ion deflector of the type described in relation to FIGS. 10 and 12 may be employed with non-annular ion trapping regions in order to reduce the peak charge density within the ion trap.

[0184] FIG. 13 shows a schematic of an embodiment of the present invention in which an ion deflector 10 is used to fill an ion trap of the type described in relation to FIG. 2. The ion deflector is used to deflect ions that are travelling into the ion trap to different positions along the X-axis of the ion trap. This may be achieved by varying the voltages applied to the electrodes of the ion deflector with time so that the ions are scanned along the X-axis of the trap. By dynamically deflecting the incoming ion beam during filling of the ion trap, the increase in local space charge observed during filling of the trap may be dramatically reduced, thereby allowing a much larger volume of the ion trap to be utilized and a higher total space-charge capacity to be realized.

[0185] FIG. 14A shows another embodiment of the invention corresponding to the arrangement shown in FIG. 2, except wherein the ion trap is extended in a direction parallel to the incoming ion beam axis, and wherein ions are driven in a direction parallel to the ion beam so as to be distributed more evenly along the ion trap. As described previously, driving ions along the ion trap towards the side or end of an ion trap would result in ions concentrating at one side or end of the trapping region, leading to increased local charge density at that region, particular for ions of high mobility. However, in the embodiment of FIG. 14A, this is somewhat mitigated by driving the ions from the entrance of the ion trap towards the exit of the ion trap using a travelling DC potential or wave that decays in amplitude as it travels from the entrance to the exit of the trap (shown in FIG. 14B). Alternatively, ions may be driven from the entrance of the ion trap towards the exit of the ion trap using a non-linear DC potential gradient that decays in amplitude in a direction from the entrance to the exit of the trap (shown in FIG. 14C), resulting in a reduction in the driving force at the exit of the trapping region as compared to the entrance of the ion trapping region. However, even using these modified fields, it is difficult to distribute ions of different mobility evenly within the trapping volume.

[0186] Although the present invention has been described with reference to various embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the scope of the invention as set forth in the accompanying claims.

[0187] For example, the deflection electrode can be used to control the filling time of the ion trap to control the total space charge in the trap. In this case the electrode directs the beam to a point outside the trapping region for a period within the fill time.