The disclosure concerns ion optical devices, ion repulsive surfaces, ion optical systems, multipole ion optical devices and mass or ion mobility spectrometers.
This disclosure concerns the manipulation and confinement of ions at atmospheric pressure. Many technical disclosures, including patent documents, purport to confine ions at pressures approaching, including and exceeding atmospheric pressure (which is referred to herein as “high pressure”) using pseudopotential effects due to radio frequency (RF) fields.
In particular, many known approaches assume that the pseudopotential effect is sufficient to confine ions at close to atmospheric pressures, for example U.S. Pat. Nos. 8,362,421, 8,835,839 (relying on inhomogeneous electric fields as described in U.S. Pat. No. 5,572,035), Tolmachev et.al. (Anal. Chem. 86 18 9162-9168 (2014)), WO-2017062102 A1, U.S. Pat. No. 9,984,861 B2, U.S. Pat. No. 8,975,578 B2, U.S. Pat. No. 8,841,611 B2, U.S. Pat. No. 8,067,747 B2 and U.S. Pat. No. 9,620,346 B2. Devices as described in these documents include arrays of electrodes having opposing phases of RF applied to them (phases that are 180 degrees different from one another) in order to create field gradients local to the electrode array, the ion oscillations in these regions of field gradient causing the pseudopotential effect to occur, resulting from a net field over each oscillation cycle (a pseudo-field) which applies a force in the direction of lower field gradient. Advantageously, the pseudo-field acts in this way on ions of either charge polarity. U.S. Pat. No. 8,299,443 B1 and U.S. Pat. No. 9,053,915 B2 take this approach further by attempting to increase the pseudopotential by operating at very high electric field strengths.
With such approaches in mind, note should be made of Tolmachev et.al. (Nucl. Intr. and Meth. in Phys. Res. B 124 (1997) 112-119), which explains that the pseudopotential is severely attenuated at atmospheric pressure, by ion-gas collisions suppressing oscillation amplitude and changing the phase shift between ion velocity and field oscillations. Significantly, U.S. Pat. No. 9,991,108 (column 2 lines 4 to 9) states: “However, efficient ion trapping with RF confining fields is difficult at pressures approaching atmospheric pressure and also at very low pressures where ions do not lose kinetic energy rapidly due to collisions with background gas molecules. Commercial atmospheric pressure IMS devices do not employ either RF ion traps or RF ion guides.”
This might suggest that existing approaches for using the pseudopotential effect to confine ions at atmospheric pressure with RF fields do not operate in practice as well as predicted by their designers. Effective and useful confinement of ions using RF fields at high pressure is a challenge.
Against this background, there are provided a number of approaches for the confinement of ions using RF fields at high pressure. These approaches may be combined and features and/or options of any one approach may be used in another approach without difficulty.
In one aspect, an arrangement is considered based around two (or more) spatially-separated electrodes for receiving ions in a high gas pressure environment. This environment may include a chamber, housing or optionally, be open without any enclosure. RF drive voltages having an asymmetric waveform are applied to the electrodes. The RF drive voltages applied to the two electrodes have the same drive frequencies (for example, same base frequency and preferably same secondary frequency components and may have the same amplitude and/or other waveform characteristics) but different phases. A high electric field strength is experienced by the received ions, in particular sufficient for ions to experience mobility variation (for example, at least 1 MV/m). A phase difference is considered of at least π/2 and in some implementations, at least π. Beneficially, an amplitude of the asymmetric waveform has an integral over time of substantially zero. The asymmetric waveform preferably has a shape defined by a sum of two or more cosine functions, although the shape may be alternatively defined by a rectangular function or a sum of rectangular functions.
A high gas pressure may be sufficiently high such that, in combination with the one or more RF drive frequencies, the phase shift between the electric field and a velocity of the received ions experiencing the electric field is substantially zero. In embodiments, the gas pressure is at least 10 kPa, 25 kPa, 50 kPa, 75 kPa, 100 kPa or atmospheric pressure (1 atm). The gas may be air.
The electrodes may be formed as two sets of interleaved electrodes, with one phase of RF applied to alternate electrodes and the other phase of RF applied to the interleaving electrodes. The electrodes may be in the same plane or provided in opposing (parallel) planes.
There may be more than two sets of electrodes generating the electric field. Each set of electrodes may receive an asymmetric RF voltage with the one or more drive frequencies, but a different phase than the other sets of electrodes. In some embodiments, two sets of electrodes may be provided in one plane and another set (or sets) may be provided in a different plane, for example a parallel, separated plane.
Although RF voltages are supplied to the sets of electrodes and generally only RF (that is, no DC) is applied to the sets of electrodes, one or more further electrodes may be provided to which one or more DC voltages may (only) be applied. This may assist in confinement of ions in other dimensions, for example. The electrode or electrodes to which DC are applied may be outside the spatial extent of the sets of electrodes, especially in such cases.
Another aspect may consider an ion repulsive surface, formed by two sets of electrodes, preferably on a substrate, which is typically planar and may be substantially electrically-insulating. Alternatively, the two sets of electrodes can be held by one or more supports positioned near the ends of the electrodes. Each of the electrodes is elongated and distributed along an axis (for example, linear or curved, with the electrodes being essentially parallel with a linear axis), alternating between an electrode from the first set and an electrode from the second set. RF voltages having an asymmetric waveform are applied to both sets of electrodes with the phase differing between the RF voltage applied to the first set and the RF voltage applied to the second set (normally, by at least π/2). The electric field strength adjacent the ion repulsive surface is high, particularly sufficient for ions to experience mobility variation (for instance, at least 1 MV/m). The ion repulsive surface may be arranged in an environment (which may be a chamber, housing or simply open) that is configured to operate at a high gas pressure (for instance, at least 10 kPa and even approaching or at atmospheric pressure), and/or in air.
Each of the electrodes (from one or more than one set) typically has the same shape, the same dimensions and the same spacing. Additionally or alternatively, one, some or each of the electrodes (from one or more than one set) may have one or more of a range of properties, including: a height that is at least as large as a gap between adjacent electrodes; a height that is smaller than a thickness of the substrate; a width that is at least as large as or larger than a gap between adjacent electrodes; a width that is smaller than 100 μm (or 50 μm in some cases); a length in the direction of elongation that is at least 2, 3, 5, 10, 20, 25 or 50 times as long as a gap between adjacent electrodes; and a cross-section (taken perpendicular to the direction of elongation) that is one of: rectangular with rounded corners; hemispherical; and semi ovoid. The lengths in the direction of elongation of some or each of the electrodes (from one or more than one set) may be substantially the same.
Each electrode of a set may be connected at one end to a respective common conductor (that receives the appropriate RF voltage). The common conductor for a first set of electrodes may be connected at one end of that set of electrodes and the common conductor for a second set of electrodes may be connected at the opposite end of that set of electrodes than the first set of electrodes.
As above, generally only RF (that is, no DC) is applied to the sets of electrodes. Other electrodes may be provided, to which a DC (only) voltage is applied. These electrodes may be substantially planar and essentially in the same plane electrodes to which RF is applied. For example, one DC electrode may be provided adjacent a first end of the RF electrodes (perpendicular to a direction of their elongation) and another DC electrode may be located adjacent the opposite end of the RF electrodes. A conductive back-plate may be provided on a side of the substrate opposite to that on which the sets of electrodes are located. A DC voltage may be applied to the conductive back-plate.
There may be more than two sets of electrodes generating the electric field (for example, as discussed above with reference to the first aspect). For example, two other sets of electrodes (third and fourth sets of electrodes), similar to the first and second sets of electrodes discussed above, may be distributed along a second axis (for instance, an extension of or parallel to the first axis, alternating between an electrode from the third set and an electrode from the fourth set. RF voltages having an asymmetric waveform are applied to the third and fourth sets of electrodes with the phase differing between the RF voltages applied to each of the first, second, third and fourth sets.
In another aspect, there may be considered an ion optical device (such as an ion guide, ion storage device, ion trap, collision cell or similar), comprising an ion repulsive surface as described herein. In one embodiment, the ion optical device further comprises a plate electrode, spatially separated from (and preferably substantially parallel to) the ion repulsive surface, so as to define an ion channel between the ion repulsive surface and the plate electrode. A DC voltage or an RF voltage with a time-invariant potential offset may be applied to the plate electrode.
In another embodiment, the ion repulsive surface may be a first ion repulsive surface and the ion optical device may further comprise a second ion repulsive surface as described herein, spatially separated from the first ion repulsive surface, so as to define one or more ion channels between the first and second ion repulsive surfaces. The electrodes of the two ion repulsive surface may be opposite to and aligned with each other. The RF voltages applied to electrodes of the ion repulsive surfaces may be same (at least in magnitude). These features may apply even where each ion repulsive surface has more than two sets of electrodes.
In some embodiments, the axes of the ion repulsive surface (or surfaces) are linear. Alternatively, the axes of the ion repulsive surface (or surfaces) may be curved, for example circular. In this case, the ion channel defines a circular flight path for ions to travel therethrough (or ion channels may define multiple circular flight paths for ions to travel therethrough).
For ion optical device according to any embodiment, the frequency of the RF voltages may be selected such that ion oscillation amplitudes are less than a substantial fraction of a width of the ion channel.
The ion optical device may have more than one ion channel. For example, a plate electrode may be used to separate between two ion repulsive surfaces, thereby defining a respective ion channel between each ion repulsive surface and the plate electrode. In this case, the polarity of the asymmetric waveform of the RF voltages applied to the two repulsive surfaces may be opposite. In another example, each ion repulsive surface may have four sets of electrodes, with two sets of electrodes along one length of the respective axis and two sets of electrodes along a different length of the respective axis. The RF voltage applied to the first two sets of electrodes may have opposite polarity to that applied to the other two sets of electrodes. Any embodiment with two ion channels to which opposite polarity RF voltages are applied may thus be able to handle ions having different ion mobility types. An upstream FAIMS separator may be used to separate ion of different ion mobility types before transferring the ions to the appropriate ion channel of the ion optical device.
A transport controller may induce movement of ions within the or each ion channel by controlling one or more of: (i) application of time-invariant potentials to create a steady-state electric field along a length of the or each ion channel; (ii) gas flow along the length of the or each ion channel; and (iii) application of travelling wave potentials to create a moving electric field along the length of the or each ion channel. The transport controller may control the application of potentials to any of the electrodes to which the RF voltages are applied and/or supplementary electrodes each positioned between the electrodes to which the RF voltages are applied.
In a further aspect, an ion optical system may be considered, comprising: an ion optical device as herein disclosed and configured to receive ions. The ion optical system may further include at least one gating electrode. A DC power supply may be configured selectively to provide a DC potential to gating electrode (or electrodes), so as to cause transfer of ions from the RF ion guide to an output device (for example, another ion optical device). An aperture in an ion repulsive surface or a plate electrode may allow ions to travel therethrough, with the output device receiving ions via the aperture. For instance, the gating electrode may be positioned on or adjacent to an ion repulsive surface (for instance on the substrate) near the aperture. Multiple gating electrodes may be used, for instance with one positioned on or adjacent to ion optical device and another positioned on or adjacent to the output device. Two different DC gating potentials may be applied to the gating electrodes, for instance to cause ions to travel from the first ion optical device through the aperture and to another ion optical device. The second ion optical device may be orientated parallel to the first ion optical device, with the first ion optical device having a first aperture in an ion repulsive surface for ions to travel therethrough and the second ion optical device having a second aperture in an ion repulsive surface for ions to be received. Alternatively, the second ion optical device may be orientated perpendicular to the first ion optical device, with the first ion optical device having an aperture in an ion repulsive surface for ions to travel therethrough and the second ion optical device being positioned such that ions can travel through the aperture and be received in an end of an ion channel of the second ion optical device.
A further aspect may be found in an ion optical system, comprising a plurality of RF ion guides, each of the plurality of RF ion guides being formed by an ion optical device as disclosed herein.
In one example of an ion optical system, each of multiple ion optical devices may comprise one or more ion repulsive surfaces, each having a respective circular axis for the first and second pluralities of electrodes. In other words, the ion channel for each ion optical device may define a respective circular flight path for ions to travel therethrough.
For instance, the plurality of RF ion guides may comprise two ion optical devices each having circular axes in respective planes, but with different (that is, offset) centres, such that the axes overlap. In particular, the axes may be in parallel planes. Ion transfer optics may transfer ions between the ion optical devices in the region in which the axes overlap. In another example, four ion optical devices may each have respective circular axes. The axes of a first pair of devices (that is, two devices) may be concentric but of different radius (and beneficially in the same plane). Similarly, the axes of a second pair of devices may be concentric, but offset from the axial centre of the first pair (and advantageously, in a plane parallel to the axial plane of the first pair). The axial radii of the second pair match those of the first pair, such that the axis with the smaller radius of one pair overlaps with the axis with the larger radius of the other pair. Ion transfer optics may transfer ions between the RF ion guides in regions in which their axes overlap.
A yet further aspect may be considered in a mass spectrometer, comprising an ion optical system as herein disclosed. The mass spectrometer may further comprise at least one ion optical processing device, configured to receive ions from the ion optical system.
Another aspect may be found in an ion optical interface between two parts of a mass spectrometry system, in which an RF ion guide is formed from an ion optical device or an ion optical system as herein disclosed. Ions are received at one end of the RF ion guide and output at the opposite end of the RF ion guide. For example, ions may be received from an ion source or some other part at atmospheric pressure. The interface may output to a part operating below atmospheric pressure. This aspect may be further found in a mass spectrometer or ion mobility spectrometer, comprising an ion source (of APCI, APPI, ESI, EI, CI, ICP or MALDI type, for instance, optionally having an ion current of at least 5 nA), an ion optical interface as herein described and an ion processing system (for example, an ion mobility analyser. An accelerating potential may be applied between the ion source and ion optical interface. The temperature of the RF ion guide in the interface may be higher than that of the ion source. An ion mobility spectrometer may be considered, comprising an ion mobility analyser formed from an ion optical device as herein described.
A multipole ion optical device may be provided. Two opposing pluralities of electrodes (for instance, each provided along a respective axis, the two axes being parallel) may define an ion channel therebetween, typically equally spaced along the respective axes. As discussed above, asymmetric RF voltages may be provided to the electrodes, with adjacent electrodes receiving RF voltages having different phases. Generally, only RF (that is, no DC) is applied to the opposing electrodes. A high strength electric field (sufficient for ions to experience mobility variation, for instance at least 1 MV/m) may be formed in ion channel. Ions may thereby be trapped. A high gas pressure is preferably used (for example, at least 10 kPa), such that there is substantially zero phase shift between the electric field and ion velocity. A ratio of a positive to negative peak voltages of the RF voltages (or a ratio of negative to positive peak voltages of the RF voltages, for instance depending on the polarity of the waveform) preferably has a magnitude of at least 2.
A simple trap may have a phase difference between adjacent electrodes of approximately π (180 degrees). In other words, this phase difference between adjacent electrodes on the same axis and adjacent electrodes between the two axes.
A more complex, multipole configuration may involve the electrodes being grouped, such that adjacent electrodes within the group (and between groups) receive RF voltages of the same waveform (frequency or frequencies) and having a phase differing by 2π divided by the number of electrodes in the group. For example, a group of four electrodes, with phase differing by approximately π/2 (90 degrees) between adjacent electrodes may provide a quadrupole ion optical device. Similarly, a group of three electrodes, with phase differing by approximately 2π/3 (120 degrees) between adjacent electrodes may provide a tripole ion optical device. It should be noted that, where multiple groups of electrodes are provided, the same phase difference should also apply between adjacent electrodes of two different groups, as between adjacent electrodes within the group. Thus, a repeating unit of six electrodes may also define an array of tripole traps.
Two adjacent multipole traps in the same ion optical device may be provided with RF voltages having opposite polarity (polarity referring to the polarity of the average voltage and/or higher peak voltage over one cycle of the asymmetric waveform). In this way, ions of different mobility types may be trapped in the same ion optical device. An upstream ion mobility separator may be used to provide ions to the two traps.
Ions may be transported within and/or traps by different approaches, which may be controlled (for example, by a controller). In one approach, a steady-state electric field may be applied to the electrodes, for instance by biasing the electrodes (and/or supplementary electrodes) with time-invariant voltages of a monotonically varying magnitude (to generate a voltage gradient). Changing the bias voltage may allow separation of ions by their mass and/or mobility. In another approach, a gas may flow through the array (the flow rate being set to cause ions of a minimum mass and/or maximum mobility to be transported, thereby making an ion mass or mobility filter possible). Gas flow may also make possible transport of ions in a direction perpendicular to that along which the electrodes are arranged. A further approach may be applying a time-varying set of voltages to the electrodes to produce a travelling wave. An electric field that moves across the array may then be caused.
Using these approaches, the ion optical device may act as one or more of: a mass filter; a mass analyser; an ion mobility filter; an ion mobility analyser; and a drift tube. A mass spectrometer or ion mobility spectrometer may also be realised.
Methods of manufacturing and/or operating any apparatus, device, system or instrument (for example, spectrometer) are also provided. This may have steps corresponding with those of any of the respective products disclosed herein (for instance, providing and/or configuring the features of the product).
The invention may be put into practice in a number of ways, and preferred embodiments will now be described by way of example only and with reference to the accompanying drawings, in which:
25B show plots of effective potential against position experienced by ions along the two test lines of
Approaches in accordance with the present disclosure improve ion repulsion and ion confinement at high pressure by utilising a differential mobility effect. Existing approaches suggest that ion repulsion and ion confinement can be achieved at high pressure due to a pseudo-potential effect. However, it has been recognised that the magnitude of this effect is much smaller than previously anticipated.
This may be because ion motion in gas at pressures approaching, including and exceeding atmospheric pressure (which is referred to herein as “high pressure”), is heavily damped due to ion-gas molecule collisions. The damping restricts the amplitude of oscillations that ions undergo in RF fields applied to multipole structures. Pseudo-potential effects rely upon the ion oscillations taking the ions into and out of higher field regions due to the field gradient, and the suppression of the ion oscillation amplitudes by ion-gas molecule collisions greatly reduces the pseudo-potential effect at high pressures. A second effect of the ion-gas molecule collisions at high pressure is that the phase shift between the ion velocity oscillation and the electric field oscillation is changed from a shift approaching −π/2 in vacuum to a shift tending towards zero in high pressure gas. This phase shift also suppresses the pseudo-potential effect, the net field experienced by an ion over the oscillation cycle tending to zero as the phase shift tends to zero.
These issues with the pseudo-potential effect will firstly be discussed, before establishing the greater magnitude of a differential mobility effect and the combination of these two effects to improve ion repulsion and ion confinement at high pressure.
Existing devices, including multipoles and planar multi-electrode structures, are driven with voltages of a sinusoidal waveform applied. They utilise pseudo-potential gradients to confine ions. Such gradients are sometimes also referred to as quasi-potentials or effective potentials. Herein, they shall be referred to as pseudo-potentials.
Pseudo-potential in vacuum is described by equation (1) below, where E0 is the peak electric field of the oscillation cycle, ω=2πf and f is the drive frequency, q is the charge on the ion and m is the ion mass. A pseudo-potential barrier requires a field gradient and does not utilise any variance in ion mobility that an ion might possess. For simplicity, and in accordance with use of the term in many existing publications, the term “pseudo-potential effect” is used herein as being the effect on an ion of a symmetrical oscillating electric field which has a field gradient, but which does not require or take any advantage of the presence of any velocity-dependent mobility variance. The field gradient is required, so that the difference in field experienced by the ion as it oscillates provides a net electric field over each oscillation cycle, from which the pseudo-potential gradient is derived.
The pseudo-potential effect is attenuated in the presence of a dense gas. The attenuation depends upon the collision rate and the energy loss of the ion due to the collisions with gas molecules. Tolmachev et.al. (Nucl. Instr. and Meth. in Phys. Res. B 124 (1997) 112-119) derived a factor, γ, to apply to the pseudo-potential in vacuum in order to obtain the pseudo-potential in the gas (equation (2) below), under the assumption that ion velocity was low such that T is not dependent on ion velocity:
where T is the relaxation time of the particular ion in the gas. The relaxation time is the time it takes the ion to slow from an initial velocity in the gas by a factor 1/e. (This is not the mean time between collisions, as is sometimes incorrectly stated in some publications.) In a gas, the pseudo-potential is then given by equation (3):
The relaxation time is related to the ion's mobility, p, by equation (4):
Equation (4) above is especially considered valid under conditions where the ion velocity remains smaller than the Maxwellian average thermal velocity of the gas molecules, which is approximately 1.35 times the speed of sound in the gas. Such conditions prevail in practical embodiments and the simulation results presented herein (subject to mobility variance, which causes variation in the relaxation time, as discussed below).
Mobility is pressure dependent. The attenuation of the pseudo-potential is therefore also pressure dependent.
At high ion velocities, the relaxation time is not a constant but is a function of the ion's velocity, since the mobility will vary if that velocity approaches the speed of sound in the gas. The attenuation factor γ therefore also varies under these conditions.
The attenuation is in part due to the smaller ion oscillation amplitude due to the damping effect of the gas, which takes the ion across a smaller field gradient, and is also in part due to the phase difference between ion velocity and electric field becoming smaller as the result of frequent collisions. At low pressures, the phase difference approaches −π/2; in a dense gas, the phase difference tends towards zero at low drive frequencies. When the phase difference is −π/2, the pseudo-potential effect is at its maximum; when the phase shift equals zero, there is no pseudo-potential effect. The phase difference depends, amongst other things, upon the density of the gas and also on the drive frequency.
In a dense gas, at low enough drive frequencies where ω2T2<<1, γ˜ω2T2. With this approximation and equation (4) above, equation (3) above is then described by equation (5) below and the pseudo-potential is seen to be independent of drive frequency. This is the maximum pseudo-potential that can be derived in high pressure gas for any frequency for the ion in question. At higher drive frequencies, the pseudo-potential falls as a result of the 1/ω2 term. Once in the regime described by equation (5), lowering the drive frequency does not result in a greater pseudo-potential, but it does produce larger ion oscillation amplitudes.
Note that in equation (5), q/m is inverted compared to the vacuum regime of equation (1) above. Equation (5) shows that the pseudo-potential follows the product of mass-to-charge ratio and mobility-squared and does not follow q/m as in vacuum (equation (1)). The product of mass-to-charge ratio and mobility squared varies across the mass range and with ion species. Typically, singly charged ions below ˜250 Da have a low product of mass and mobility squared and are more difficult to confine using pseudo-potential when the gas pressure is high (approaching atmospheric pressure).
The attenuation is substantial and pseudo-potential at atmospheric pressure is low, requiring very high electric fields to be sufficient to confine ions. In high fields, the ion velocity is a substantial fraction of the speed of sound in the gas and mobility varies with the ion velocity. This understanding is utilised and further developed in the present disclosure.
As noted above, attempts suggested in U.S. Pat. No. 8,299,443 B1 and U.S. Pat. No. 9,053,915 B2 to increase the pseudo-potential at high pressures by operating them at very high electric strengths, have effects not recognised by those publications. At the high electric fields and the operating pressures proposed in these documents, the ion velocity for part of the electric field cycle is sufficiently high that the ion mobility is no longer invariant. These changes to the ion mobility affect the pseudo-potential (equation (5) above), as will be described below.
With a time-varying electric field, the variance of mobility as ion velocity approaches the speed of sound in the gas can be used to give the ions a net velocity over each cycle, if the electric field experienced by the ion is asymmetric.
Referring to
Thus, the form of the asymmetry may be relevant. Referring next to
This waveform has an asymmetry that has different proportions of the cycle given to the two opposite polarities. This asymmetric waveform applies a large field in one direction (first polarity) for a small proportion of the cycle and a smaller field in the opposite direction (second polarity) for a larger proportion of the cycle. The smaller and larger proportions of time and electric field magnitudes are chosen so that the area under the waveform (electric field strength multiplied by time) is zero over a cycle. This is achieved, for example, with the waveform shown in
The waveform of equation (6) and
Reference is now made to
Type B ions having characteristics as shown in
This difference due to the ion mobility variance at high velocity (the differential ion mobility) is used in Field Asymmetric Ion Mobility Spectrometry (FAIMS) to separate ions. The net velocity an ion attains over each cycle due to this effect is referred to herein as a “differential mobility effect”. This effect demands: (1) the ions have a mobility which varies with ion velocity (probably all ions possess this property to some degree); (2) the ions experience some form of asymmetric electric field over each cycle, the asymmetry being such that the peak field is higher than average when at one polarity and lower than average when at the opposite polarity; and (3) the peak electric field is high enough at the pressure concerned to cause the ion velocity to exceed a substantial fraction of the speed of sound in the gas, so that for some of the cycle the ion mobility is not constant.
More generally in the field of ion mobility spectrometry, a sufficient field strength to cause the differential mobility effect to occur is referred to as a “high field”. Conversely, the high field may be understood a field strength that is sufficiently high: to cause a non-linear dependence of ion mobility; and/or such that the mobility of ions is dependent on the field strength. This is typically at least 106 V/m, although mobility variance with electric field may start to occur for some ion species in fields as low as 2.5×105 V/m (Viehland, Guevremont, Purves & Barnet, Int. J. Mass Spectrom. 197 123-130 2000). For example, this is discussed in “Ion Mobility Spectrometry”, G. A. Eiceman, Z. Karpas, Second Edition, CRC Press, 23 Jun. 2005, section 2.5 (“Dependence of Mobility on Electric Field”).
As noted above, the differential mobility effect is utilised in a flat plate FAIMS analyser. This analyser comprises two parallel flat plate electrodes, (as in a capacitor). If the analyser has plates having dimensions much larger than the gap between the plates (for instance, at least 10%, 20%, 25%, 50% or 100% larger), the field strength away from the plate edges is substantially invariant with position and there is no field gradient. One plate of the analyser is provided with an asymmetric voltage waveform, which may be a rectangular waveform, or, as described herein, a waveform of similar shape to that in
The pseudo-potential effect and differential mobility effect have thus far been described separately, but it can immediately be recognised that the two effects interact. Consequently, the motion of ions can be controlled by both effects together. Conversely, it is possible to confuse the two effects.
The differential mobility effect requires a mobility variance with ion velocity and does not require any field gradient. Nevertheless, the presence of a field gradient can cause an ion to undergo an asymmetric electric field over a cycle. The pseudo-potential changes due to changing ion mobility with ion velocity, as has already been noted in relation to equation (5) above. Now, it can be seen that a net drift velocity is induced in ions by an asymmetric electric field acting on the ions, derived from a symmetrical electric field waveform plus a field gradient—as long as the field is sufficient to induce ion velocities approaching the speed of sound in the gas for a proportion of the cycle.
This affects the pseudo-potential effect. The pseudo-potential effect does not require any mobility variance, but the presence of ion mobility variance when the applied field strengths are sufficiently high at the prevailing pressure causes changes to the net drift velocity and hence the pseudo-potential, the changes coming from the differential mobility effect.
The two effects can therefore be distinguished by modelling in the same field otherwise identical ions that have no mobility variance. Any net motion per cycle of these ions can only be due to the pseudo-potential effect. Subtracting the net motion of these ions from the motion of ions that do possess mobility variance reveals the net drift velocity due to this differential mobility effect alone. This simulation technique for separating out the different effects of the pseudo-potential and differential ion mobility is only useful if there is a field gradient. In the flat plate analyser described above, the pseudo-potential effect does not occur and pseudo-potential is zero because there is no field gradient.
Known devices that utilise pseudo-potential to confine ions at high pressures include multipoles (for example, U.S. Pat. No. 8,362,421 B2) and opposing substrates having a plurality of strip electrodes formed on each substrate (for example, U.S. Pat. No. 10,014,167 B2, U.S. Pat. No. 8,835,839 B1, WO-2017/062102 A1, U.S. Pat. No. 8,841,611 B2, U.S. Pat. No. 9,245,725 B2, U.S. Pat. No. 8,299,443 B1, U.S. Pat. No. 8,067,747 B2, U.S. Pat. No. 9,053,915 B2). Strip electrodes are often aligned on the opposing substrates and as such can form an array of multipole devices and hence are not dissimilar to the multipoles contemplated by U.S. Pat. No. 8,362,421 B2. The operation of such devices will now be discussed based on modelling and simulation.
Referring now to
Sinusoidal RF voltages applied to the electrodes are split in phase, adjacent electrodes having a phase shift of 180 degrees applied. The strip electrodes are 50 μm wide (in the x-direction) with rounded corners of radius 3.5 μm, the gap between adjacent electrodes on the same substrate is 50 μm and the electrode height (in the y-direction) is 30 μm. The gap between the opposing strip electrode surfaces on opposing substrates is 50 μm. Unless otherwise stated, the ion motion simulations herein are for positively charged ions in air at atmospheric pressure (101325 Pa) and room temperature (293 K).
As an example, a sinusoidal voltage waveform of 100 V zero-to-peak voltage at 60 MHz is applied to the electrodes of
Referring to
Referring next to
Now referring to
Next referring to
Referring to
Reference is now made to
At the field strength in this example, ions of type A mobility variance experience a pseudo-potential approximately a factor of two larger than mobility-invariant ions and a factor four larger than type C ions. The maximum pseudo-potential well is only some 0.4 V for type A ions, even though the field strength within the trapping region is in excess of 4 million V/m. The effect of pseudo-potential can be seen as low in magnitude and highly variable with ion type. Existing electrode arrangement designs did not take this into account and may explains why, in the words of U.S. Pat. No. 9,991,108 (column 2 lines 4-9): “Commercial atmospheric pressure IMS devices do not employ either RF ion traps or RF ion guides.”
The pseudo-potential effect describes a net ion velocity from each oscillation cycle. The pseudo-potential can be calculated by considering the ion motion under the action of the electric field in the presence of the gas, which can be calculated by numerical methods, solving equation (8) below. The solution to equation (8) is referred to herein as an ‘average’ ion trajectory, because equation (8) does not take into account the effects of diffusion. Diffusion will cause ions to spread in all three degrees of freedom, but the average ion trajectory is nonetheless described by the solution to equation (8).
The relaxation time in equation (8), T(t), is found using equation (4) above and mobility variance with ion velocity is as depicted in
Reference is now made to
Reference is now made to
Comparison of
Increasing the voltage to obtain higher pseudo-potential is effective for type A ions but of limited use for type C ions, especially those of low mass. The higher field strengths drive higher mobility ion species at velocities, which reach and may exceed the speed of sound in the gas. The decreased ion mobility that results diminishes the pseudo-potential experienced by type C ions.
The higher field strengths to trap high mobility ions may also result in larger oscillation amplitudes, which limit the volume of space within the electrode structure that ions can remain in and not strike electrodes and be lost. Larger oscillation amplitudes are experienced by high mobility ions, which tend to be low mass ions. A practical issue is that, in order to generate the higher electric fields whilst avoiding breakdown within the air at atmospheric pressure, smaller gaps between electrodes may be necessary, as study of the Paschen curve shows. This is one of the reasons that the electrodes being described are a few tens of microns in size. However, such high fields generating larger oscillation amplitudes may reduce the volume of space in which such ions can remain stable between the electrodes for high mobility ions. Attempts to increase the field strength to trap high mobility ions better may result in smaller and smaller volumes of space in which those ions are stable.
The method for deriving the effective potential experienced by ions calculated by numerical methods solving equation (8) above demands an asymmetric voltage waveform to be applied to the electrodes. In assessing the effective potential, equations (1), (3) and (5) above no longer apply, as they were derived for the pseudo-potential effect requiring a field gradient, and for a sinusoidal field in the low velocity approximation. Instead, ion motion under the action of the electric field in the presence of the gas is calculated by numerical methods, solving equation (8), which takes into account all effects so far discussed, whether due to motion in an asymmetric electric field, whatever voltage waveform is applied and whatever the mobility variation with ion velocity.
The differential mobility effect is affected by the phase difference between the electric field and the ion velocity. However, it has been discovered that the effect is the inverse of that for the pseudo-potential. The differential mobility effect is zero in vacuum, when the phase difference between the electric field and ion velocity is −π/2. For ions moving through a gas, as the RF drive frequency is increased, the phase shift tends to that in vacuum and the differential mobility effect diminishes. Consider an electric field waveform consisting of a two-term cosine, such as that given by equation (6) above, created in the FAIMS flat plate analyser discussed above. Then, the ion velocity is also a two-term cosine, but each term is multiplied by the cosine of a phase shift, which is the arc-tangent of −ωT (where ω is the angular frequency of the relevant cosine term). The phase shift is therefore different for each cosine term. Again, T is a function of the electric field strength and so varies over the oscillation cycle.
As the differential mobility effect diminishes as the phase difference tends to −π/2, the frequency is chosen to be low enough so that ω2T2<<1 and γ˜ω2T2 for all cosine terms in the applied voltage waveform for the ion of interest, which has the lowest ion mobility. This is intended to keep all phase shift terms close to zero, which provides a maximum differential mobility effect. It also has the effect of being on the plateau of maximum pseudo-potential, so that whatever small amount of residual pseudo-potential remains available in the high pressure gas, it is at its maximum. In summary, a key aspect of the disclosure may be found in the application of an asymmetrical voltage waveform to electrodes having an RF frequency, such that the combination of RF frequency and the gas pressure produces a phase shift that is close to zero. A magnitude of the phase shift is preferably not more than (or less than) 0.1π, more preferably not more than (or less than) 0.05π, even more preferably not more than (or less than) 0.02π and possibly not more than (or less than) 0.01π. A phase shift of not more than (or less than) 0.005π or 0.001π may even be possible.
It can be understood from the above discussion that two electrodes may be sufficient for controlling ions in high pressures (for instance, approaching atmospheric, particularly tens of kPa). RF potentials having an asymmetric waveform of differing phase are applied to the two electrodes, such that the strength of the electric field experienced by ions coming close to the electrodes causes mobility variation. This application of RF voltages causing mobility variation is sufficient at high pressures to control the ions and even confine them. The two electrode pattern may be repeated to create larger control and/or confinement.
The most basic arrangement therefore, only comprises two electrodes or more preferably, two groups of electrodes, to which suitable RF potentials are applied. DC voltages may be applied to these electrodes, but more typically, only RF (that is, no DC, such as a FAIMS compensation voltage) is applied to the sets of electrodes. Instead, a third electrode (or third group of electrodes) with DC voltages applied is provided. A possible electrode arrangement for achieving control along these lines, or at least acting as an ion repelling surface, is now discussed.
Reference is now made to
In one implementation, each strip electrode width (in x) is 25 μm, and height (in y) 15 μm, the gaps between adjacent strip electrodes are 15 μm, and the distance from the outer faces of the strip electrodes to the flat plate electrode is 100 μm. The outer corners of the strip electrodes are rounded with a radius of 2.5 μm to avoid sharp corners, which may generate very high electric fields locally. The strip electrodes are many times longer (in z) than is the gap between the substrate and the flat plate electrode. The array extends (in x)+/−6 multiples of the gap between the substrate and the flat plate electrode and we obtain results in the central portion.
One general sense of the disclosure will now be discussed, before discussing more sophisticated implementations using the specific embodiments considered above. In general terms and according to this aspect, there may be considered an ion optical device comprising: first and second electrode arrangements, spatially separated from one another, arranged to receive ions and a gas and further arranged to operate in an environment having a high gas pressure; and an RF voltage supply, configured to apply: a first RF voltage of one or more RF drive frequencies to the first electrode arrangement; and a second RF voltage of the one or more RF drive frequencies, having a different phase than the first RF voltage, to the second electrode arrangement (for instance, a phase difference of at least π/2), wherein the first and second RF voltages have an asymmetric waveform (preferably having an integral over time of substantially zero), the application of the first and second RF voltages to the first and second electrodes arrangements respectively causing the received ions to experience an electric field. The asymmetric waveform may have a shape defined by a sum of two or more cosine functions or by a rectangular function or sum of rectangular functions. In that case, the asymmetric waveform has a base frequency (main frequency component) and may have one or more secondary frequency components. The environment (and/or the ion optical device) may include a housing or chamber. Generally, only RF (that is, no DC, such as a FAIMS compensation voltage) is applied to the first and second electrode arrangements.
The first and second electrode arrangements and the RF voltage supply are configured such that a strength of the electric field experienced by the received ions is high and beneficially sufficiently high for ions to experience mobility variation (in some embodiments, at least 1 MV/m). Advantageously, the first and second electrode arrangements are arranged (or the housing is configured) to operate in an environment having a gas pressure that is sufficiently high such that, in combination with the one or more RF drive frequencies, the phase shift between the electric field and a velocity of the received ions experiencing the electric field is substantially zero. For example, a gas pressure of at least 10 kPa may be considered. The gas may be air.
In one embodiment, the first electrode arrangement comprises a plurality of first (elongated) electrodes and the second electrode arrangement comprises a plurality of second (elongated) electrodes interleaved with the first electrodes. Additionally or alternatively, the first electrode arrangement and the second electrode arrangement may be positioned in a same plane. For example, the first and second electrode arrangements may be arranged on a substantially insulating substrate.
In some embodiments of the present disclosure, multiple elongated electrodes are arranged in an array on a substantially insulating substrate, where the direction of elongation is similar for each electrode, forming a set of substantially parallel electrodes. This may be termed an array of strip electrodes. The substrate is substantially planar. A single substrate of this type in a high pressure gas can be used to repel ions from the outer surface of the strip electrodes. The array of electrodes may be manufactured using conventional MEMS techniques.
In embodiments, a third electrode arrangement may be, spatially separated from the first electrode arrangement and the second electrode arrangement. The third electrode arrangement may be arranged to operate in the environment having a high gas pressure. Then, the RF voltage supply may be further configured to apply a third RF voltage of the one or more RF drive frequencies, having a different phase than the first RF voltage and than the second RF voltage, to the third electrode arrangement. Advantageously, the third RF voltage has an asymmetric waveform. As a result, the application of the first, second and third RF voltages to the first, second and third electrodes arrangements respectively causes the received ions to experience the electric field. Optionally, the first and second electrode arrangements are positioned in a first plane and the third electrode arrangement is positioned in a second plane that is substantially parallel to and spatially separated from the first plane.
The ion optical device may further comprise: a DC electrode arrangement; and a DC voltage supply, configured to apply a DC voltage to the DC electrode arrangement. For instance, the DC electrode arrangement may be positioned outside a spatial extent of the first and second electrode arrangements. The DC electrode arrangement may be arranged parallel to or perpendicular to a direction of elongation of the first and second electrode arrangements. The DC electrode arrangement and DC voltage supply may be configured to confine ions beyond the extent of the RF electrode arrangements.
Reference is again made to
Referring now to
A conductive back plate can also be applied to the substrate. Such an electrode can then be advantageously biased so as to create an electric field in the y direction in the troughs between the strip electrodes. This electric field may serve to repel ions from the troughs.
In a first example, a two-term cosine voltage waveform, as described by equation (6) above and shown in
The electric field created in the space between the flat plate and the strip electrodes is arranged to apply a force onto a chosen charge polarity of ions of interest, the force being towards the strip electrode array. In the example considered, the ions of interest have positive charge polarity. In this example there is no back-plate to the substrate.
The RF voltages are split into two phases, with a first phase applied to electrodes 1, 3, 5, 7 and a second phase having 180 degrees difference being applied to electrodes 2, 4, 6, 8, this waveform being the sum of two cosine terms as in equation (6) above. Thus, the voltage difference between two electrodes of differing phase is given by equation (9).
Referring to
Reference is now made to
Reference is now made to
Now, referring to
Referring next to
It can therefore be seen that higher mass ions have a smaller oscillation amplitude and are therefore able to get closer to electrodes before their oscillations take them into contact with the electrode. The effective potential can therefore be determined closer to electrodes for ions of higher mass. The volume of space between the flat plate electrode and the strip electrodes may be larger for such ions, and such ions are stable at distances closer to the strip electrodes.
Reference is now made to
Ions move into the bottom of the effective potential well, some few microns from the surface of the strip electrodes. Once there, the barrier to moving along the array (in x) is low (see
In other embodiments, the flat plate electrode may be replaced with a second substrate having a second array of strip electrodes the same as the first array of strip electrodes 110 and being arranged facing and substantially parallel to the first array, such that an ion channel is thereby created in the space between the two arrays of strip electrodes. The strip electrodes of the first and second arrays are aligned and have the same voltage waveform applied.
Devices of this type (as well as other devices as disclosed herein) may be used as part of an interface between an atmospheric pressure ion source and downstream ion optics, particularly operative at lower pressures. An accelerating potential may be applied between the ion source and the interface. This may be used for mass spectrometry and/or ion mobility analysis. For example, reference is made to
Referring to
Referring to
In an aspect of the disclosure (which may be combined with other aspects described herein), there may be provided an ion repulsive surface, comprising: a first plurality of elongated electrodes distributed along an axis (which may be linear and/or curved), configured to receive a first RF voltage with an asymmetric waveform; and a second plurality of elongated electrodes distributed along the axis, the second plurality of electrodes being interleaved with the first plurality of electrodes and configured to receive a second RF voltage with an asymmetric waveform, having a different phase than the first RF voltage. If the axis is linear, the first and second pluralities of elongated electrodes are beneficially substantially parallel. Alternatively (and as will be discussed more below), the axis of the first and second pluralities of electrodes of each ion repulsive surface may be circular, such that the ion channel defines a circular flight path for ions to travel therethrough. The first plurality of elongated electrodes and/or the second plurality of electrodes are preferably on a substrate. Alternatively, one or both pluralities of electrodes may be supported at their ends (for example, similar to the rods in a conventional quadrupole ion optical device).
There may also be considered a method of manufacturing and/or operating an ion repulsive surface, an ion optical device, an ion optical system or a spectrometer (which may be combined with other aspects described herein). This may have steps corresponding with those of any of the apparatus, devices or systems disclosed herein. For example, these may include: providing a first plurality of elongated electrodes distributed along an axis (which may be linear and/or curved); receiving a first RF voltage with an asymmetric waveform at the first plurality of electrodes; providing a second plurality of elongated electrodes distributed along the axis, the second plurality of electrodes being interleaved with the first plurality of electrodes; receiving a second RF voltage with an asymmetric waveform, having a different phase than the first RF voltage at the second plurality of electrodes.
The first and second plurality of electrodes and first and second RF voltages are advantageously configured such that a strength of an electric field adjacent the ion repulsive surface is high, particularly sufficient for ions to experience mobility variation. For instance, the first and second plurality of electrodes and first and second RF voltages may be configured such that a strength of an electric field adjacent the ion repulsive surface is at least 1 MV/m and/or a phase difference between the first RF voltage and the second RF voltage is at least π/2. The ion repulsive surface may be provided in an environment (such as a housing, chamber or open environment) configured to operate at a high gas pressure (at least 10 kPa, 25 kPa, 50 kPa or 75 kPa). The gas may be air. Generally, only RF (that is, no DC, such as a FAIMS compensation voltage) is applied to the first and second pluralities of elongated electrodes.
In embodiments, the substrate is substantially electrically-insulating, for instance formed of or comprising one or more of: a ceramic material; a polymer; or a printed circuit board material. However, the substrates used are preferably slightly conductive, sufficient to avoid charging. Additionally or alternatively, the substrate may be planar.
Optionally, each of the first plurality of electrodes and/or each of the second plurality of electrodes have one or more of: the same shape, the same dimensions and the same spacing; a height that is at least as large as a gap between adjacent electrodes; a height that is smaller than a thickness of the substrate; a width that is at least as large as or larger than a gap between adjacent electrodes; a width that is smaller than 100 μm (preferably 50 μm); a length in the direction of elongation that is at least 2, 3, 5, 10, 20, 25 or 50 times as long as a gap between adjacent electrodes; and a cross-section (in particular, taken perpendicular to the direction of elongation) that is one of: rectangular, preferably with rounded corners; hemispherical; and semi ovoid. The lengths in the direction of elongation of some or each of the electrodes (from one or more than one set) may be substantially the same.
The elongated strip electrodes preferably have a height (in y) which is similar to, as large as, or larger than the gap between adjacent electrodes, so that the exposed substrate is at the bottom of the trough which is formed between adjacent strip electrodes and the depth of the trough is similar to its width. The electric field produced in the ion channel from charging of the exposed substrate in the bottom of the troughs is then greatly reduced. Simulations indicate that, under these conditions, charging to several tens of volts of the substrate in the bottom of such a trough need not disturb ions in the ion channel to significant degree. It has also been found that if ions are being transported through the ion channel by use of a gas flow, or a supplementary electric field, for example, motion is more stable in the x direction than if ions are moved in the z direction, when charging of the exposed substrate in the bottom of the troughs is present. Ions moving in the x direction cross strip electrodes and troughs successively and the average effect of a charged trough is reduced. Moving in the z direction places ions above troughs for extended proportions of time and their trajectories are more affected by the charging of the exposed substrate.
In an implementation, each of the first plurality of electrodes is connected to a first common conductor (for instance, configured to receive the first RF voltage) at a first end of the first plurality of electrodes. Then, each of the second plurality of electrodes may be connected to a second common conductor (in particular, configured to receive the second RF voltage) at a first end of the second plurality of electrodes. Here, the first end of the second plurality of electrodes is distal the first end of the first plurality of electrodes.
In some embodiments ions are free to move in the direction parallel to the elongation of the electrodes (termed herein as the z direction). Ions can be retained, for example in the z direction, by the placement of additional (elongated) electrodes on the substrate (“blocking electrodes”), for instance just beyond the ends of the pluralities of (strip) electrodes, and running in the x direction. For instance, a DC electrode arrangement is preferably provided, comprising one or more electrodes configured to receive a DC (only) voltage. Each of the one or more electrodes may have a planar form and be positioned in substantially the same plane as the first plurality of electrodes and the second plurality of electrodes. Optionally, the DC electrode arrangement comprises: a first DC electrode located adjacent a first end of the first and second pluralities of electrodes perpendicular to a direction of elongation; and a second DC electrode located adjacent a second end of the first and second pluralities of electrodes perpendicular to a direction of elongation, distal the first end. Thus, the blocking electrodes may be at either end of the array of elongated electrodes to confine the ions by being biased with a time-invariant potential. Ions may then be free to expand along the array of strip electrodes in +/−z directions under the influence of space charge until they reach the vicinity of the blocking electrodes. A large length of the elongated array electrodes may allow much larger ion currents to be used as the space charge capacity of the structure is enhanced. Ions can be moved in the x direction through the array (as will be further described below) or ions may be moved in the z direction, by the use of a gas flow or a supplementary electric field.
In embodiments, a conductive back-plate is provided on a side of the substrate opposite to a side on which the first and second plurality of electrodes are located. The conductive back-plate may be configured to receive a DC voltage. The DC voltage may create an electric field in the y direction in the troughs between the strip electrodes, which may serve to repel ions from the troughs.
More than two groups of electrodes may be provided on the substrate. For example, the ion repulsive surface (or an ion optical device comprising the ion repulsive surface) may further comprise: a third plurality of elongated electrodes on the substrate, distributed along a second axis and distinct from the first and second pluralities of electrodes and configured to receive a third RF voltage with an asymmetric waveform having a different phase than the first and second RF voltages. In addition, there may be provided a fourth plurality of elongated electrodes on the substrate, the fourth plurality of electrodes being interleaved with the third plurality of electrodes along the second axis and configured to receive a fourth RF voltage with an asymmetric waveform, having a different phase than the first, second and third RF voltages. Advantageously, the second axis is an extension to the first axis, such that the third and/or fourth pluralities of electrodes are formed on the same substrate as the first and second pluralities of electrodes. Alternatively (as will be discussed further below), the second axis may be parallel to the first axis, with the third and/or fourth pluralities of electrodes being formed on a different substrate to the first and second pluralities of electrodes.
In many embodiments a second substantially planar surface is placed (preferably) parallel to the first substrate (and/or ion repulsive surface). For example, an ion optical device according to some embodiments may be provided, comprising: an ion repulsive surface as disclosed herein; and a plate electrode, spatially separated from the ion repulsive surface, so as to define an ion channel between the ion repulsive surface and the plate electrode. For example, the plate electrode may be configured to receive a DC voltage or an RF voltage with a time-invariant potential offset. The plate electrode may be biased with a potential that differs from the average potential applied to the pluralities of electrodes of the ion repulsive surface and is of a polarity to repel ions towards the ion repulsive surface. In this embodiment, the plate electrode bias creates an electric field in the ion channel (in the y direction), such that the gap between the first substrate and the plate electrode can be within a range of sizes. A larger gap may demand a larger potential difference to create the same strength of electric field. The electric field creates a force on the ions and the electrodes of the ion repulsive surface create an opposing force, holding the ions within a region of the ion channel. Beneficially, the plate electrode is substantially parallel to the ion repulsive surface. In other embodiments, the gap between the plate electrode and the substrate may vary (or an electrode of different shape may be used), for instance to increase or decrease the gap across the ion channel, so as to alter the electric field strength across the ion channel at different locations. In this way, an axial DC field gradient may be provided. The frequency (in particular, the base frequency) of the first and second RF voltages may be selected such that ion oscillation amplitudes are less than a substantial fraction of a width of the ion channel. Other second surfaces will be discussed below.
Another aspect of the present disclosure may be found in an ion optical system, comprising a plurality of RF ion guides, each of the plurality of RF ion guides being formed by an ion optical device as herein disclosed.
A further aspect may be seen in a mass spectrometer, comprising: an ion optical system as herein disclosed; and at least one ion optical processing device, configured to receive ions from the ion optical system. Alternatively, there may be considered an ion mobility spectrometer, comprising an ion mobility analyser formed from an ion optical device or an ion optical system as herein described.
In an additional aspect, there may be considered an ion optical interface between a first part of a mass spectrometry system and a second part of a mass spectrometry system, comprising an RF ion guide formed from an ion optical device or an ion optical system as herein disclosed. In this case, the RF ion guide may be configured to receive ions from the first part of the mass spectrometry system at a first end of the RF ion guide and to output ions at a second opposite end of the RF ion guide towards the second part of the mass spectrometry system. For example, the first part of the mass spectrometry system may comprise an ion source. In an advantageous implementation, the first end of the RF ion guide is arranged to operate at atmospheric pressure and the second end of the RF ion guide is arranged to operate at pressure below atmospheric pressure.
The ion optical interface may form part of a mass or ion mobility spectrometer that preferably further comprises an ion source, configured to generate ions to be received at the ion optical interface. For example, the ion source comprises one of: an Atmospheric Pressure Chemical Ionization (APCI) ion source; an Atmospheric Pressure Photoionization (APPI) ion source; an Electrospray Ionization (ESI) ion source; an Electron Ionization (EI) ion source; a Chemical Ionization (CI) ion source; an Inductively Coupled Plasma (ICP) ion source; and a Matrix Assisted Laser Desorption Ionization, (MALDI) ion source. A potential difference between the ion source and the ion optical interface in operation may cause ions generated by the ion source to travel to the RF ion guide and enter the first end of the RF ion guide. Additionally or alternatively, a temperature of RF ion guide in operation may be higher than that of the ion source. The ion source may be configured to generate an ion current of at least 5 nA.
An ion processing system may then be configured to receive ions from the ion optical interface. For instance, the ion processing system may comprise an ion mobility analyser, arranged to receive ions from the RF ion guide and separate the received ions according to their respective ion mobilities.
Further reference will be made to this general sense below. Now, other specific embodiments are discussed.
Simple Ion Optical Devices for More than One Type of Ions
Reference is now made to
A double structure is employed. A first substrate (not shown), on which are provided a strip electrode array 210 having a first polarity asymmetric RF voltage waveform applied to the electrodes, is separated from a substantially parallel second substrate (not shown), on which a strip electrode array 230 is formed having a second opposite polarity voltage waveform applied to the electrodes, by a flat plate electrode 220. Two ion channels are thereby formed, a first ion channel 215 between the first substrate and the flat plate electrode 220, and a second ion channel 225 between the second substrate and the flat plate electrode.
The first ion channel 215 is arranged to transmit ions of type C mobility variance, by the choice of polarity of the voltage waveform applied to the strip electrodes 210 on the first substrate, and the second ion channel 225 is arranged to transmit ions of type A mobility variance by the choice of polarity of the voltage waveform applied to the strip electrodes 230 of the second substrate. The flat plate electrode 220 serves to generate an electric field which applies a force to both type C and type A mobility variance ions, for example by applying a DC voltage to the plate electrode, the force being towards the respective strip electrode array. By this means, a given charge polarity of ions of both type A and type C mobility variance is transmitted.
Advantageously, the separation of type C and type A ions may be accomplished upstream of the device in
Reference is now made to
Now, referring to
It is noted how there is a considerable residual pseudo-potential effect for ions of mass 1000 Da (
Referring next to
The arrays of electrodes form traps for ions of a given mobility variance. Groups of electrodes are provided with a voltage waveform of one polarity and other groups of electrodes are provided with a voltage waveform of the opposite polarity, the groups of electrodes all being upon a single substrate.
Referring to
With reference to
Now, referring to
With reference to
Now, referring to
It can therefore be seen that a range of potential well locations are created for the different ions, separating ions in space. The use of alternate polarity waveforms on different pairs of electrodes enables ions of type C and type A to be repelled from the single substrate. The alternate polarity waveforms may be applied to adjacent pairs of electrodes, but more preferably they are applied to groups of the electrodes, each group having at least three electrodes within it. Type C ions are repelled from the areas of the substrate in which the polarity of the two-term cosine voltage waveform is negative polarity and type A ions are repelled from the areas of the substrate in which the polarity of the two-term cosine voltage waveform is positive polarity.
The effective potential barrier experienced by the ions in the x direction (across the array) once in or close to the potential well in the y direction is shown in
Based on evidence available it is suggested that, if the groups of electrodes having opposite polarity have only small numbers of strip electrodes, such as only two, for example, and the two groups are adjacent one other, ions getting close to the border between adjacent groups may become unstable and move into the region where the polarity of the voltage waveform produces an effective potential hill driving the ions onto the strip electrodes. It is therefore advantageous to have more than two electrodes in each group. This effect can be appreciated when comparing
Referring next to
Pairs of electrodes 410 are provided with a voltage waveform of one polarity and other pairs of electrodes 410 are provided with a voltage waveform of the opposite polarity, all these electrodes 410 being upon a first substrate. Preferably, the following approach is taken. A first group of strip electrodes comprises two or more pairs of contiguous electrodes (labelled 1 and 2) having asymmetrical negative polarity voltage waveforms applied, alternate electrodes within the group having a phase shift in the voltages applied between them. A second group of strip electrodes, which comprises two or more pairs of contiguous electrodes (labelled 3 and 4), have asymmetrical positive polarity voltage waveforms applied. Alternate electrodes within the group have a phase shift in the voltages applied between them. The phase shift is preferably 180 degrees.
A second substrate having the same pattern of strip electrodes 420 is provided and is arranged to face the first substrate and be in alignment with it. The strip electrodes of the two substrates are aligned and have the same voltage waveform applied.
With reference to
Now, referring to
Now, referring to
It has been discovered that, if the groups of electrodes having opposite polarity have only small numbers of strip electrodes (for example, only two) and the two groups are adjacent one other, ions getting close to the border between adjacent groups may become unstable and move into the region where the polarity of the voltage waveform produces an effective potential hill driving the ions onto the strip electrodes. It is therefore advantageous to have more than two electrodes in each group. This effect can be appreciated when comparing
With reference to a general sense of the disclosure discussed above, another aspect of the disclosure may be found in an ion optical device, comprising a second substantially planar surface facing the ion repulsive surface. For example, the ion optical device may comprise: a first ion repulsive surface as herein disclosed; and a second ion repulsive surface as herein disclosed, spatially separated from the first ion repulsive surface, so as to define an ion channel between the first and second ion repulsive surfaces. In other words, the second substantially planar surface may be a second substrate of strip electrodes with the outer surfaces of the electrodes facing the outer surface of the electrodes of the first substrate. The space created between the outer surfaces of the two arrays of strip electrodes forms a channel, and typically that channel is of a size similar to or a few multiples of the spacing between strip electrodes (for instance, between 1 and 4 times, or between 1 and 3 times or between 1 and 2 times the spacing between strip electrodes), so that ions may be injected into this channel. The arrays of strip electrodes of the two substrates can be all elongated in the same (z) direction, and they can be aligned with each other. Alternatively, the strip electrodes on one substrate can be arranged at an angle to those of the second substrate. The angle can be 90 degrees. As with other ion optical devices considered herein, the frequency of the first and second RF voltages (especially the base frequency) may be selected such that ion oscillation amplitudes are less than a substantial fraction of a width of the ion channel. As above, an ion optical system, comprising a plurality of RF ion guides, each of the plurality of RF ion guides being formed by an ion optical device as herein disclosed may also be considered.
Optionally, a plate electrode may be positioned between and spatially separated from the first and second ion repulsive surfaces, so as to define a first ion channel between the first ion repulsive surface and the plate electrode and a second ion channel between the second ion repulsive surface and the plate electrode. Then, the first and second RF voltages of the first ion repulsive surface may have opposite polarity from the first and second RF voltages of the second ion repulsive surface. This may allow the first and second ion channels to transport ions of different mobility types. A FAIMS separator may be provided upstream the ion optical device, configured to separate ions according to their ion mobility type and direct a first type of ions to the first ion channel and a second type of ions to the second ion channel.
In the ion optical device, the first plurality of electrodes of the first ion repulsive surface are advantageously arranged to be aligned with and opposite the first plurality of electrodes of the second ion repulsive surface and/or the second plurality of electrodes of the first ion repulsive surface are arranged to be aligned with and opposite the second plurality of electrodes of the second ion repulsive surface. Then, the first RF voltage of the first ion repulsive surface is typically the same as the first RF voltage of the second ion repulsive surface and/or the second RF voltage of the first ion repulsive surface is typically the same as the second RF voltage of the second ion repulsive surface.
In some embodiments, each of the first and/or second ion repulsive surface have more than two respective pluralities of electrodes, for example having four pluralities of electrodes (each receiving a RF voltage of different phase), as discussed above. Then, the third plurality of electrodes of the first ion repulsive surface may be aligned with and opposite the third plurality of electrodes of the second ion repulsive surface and/or the fourth plurality of electrodes of the first ion repulsive surface may be aligned with and opposite the fourth plurality of electrodes of the second ion repulsive surface. Then, the third RF voltage of the first ion repulsive surface is typically the same as the third RF voltage of the second ion repulsive surface and/or the fourth RF voltage of the first ion repulsive surface is typically the same as the fourth RF voltage of the second ion repulsive surface. In such configurations, the first RF voltage and the third RF voltage may have opposite polarity and/or the second RF voltage and the fourth RF voltage may have opposite polarity (polarity in this context being defined by an average (mean) voltage or the polarity of the higher peak voltage across one cycle of a waveform of the respective RF voltage).
Transfer from One Pair of Opposing Strip Electrode Arrays to Another
Referring now to
The second ion guide 520 has a lower voltage offset (for positive ions) than the first ion guide 510. For transmission of ions through the first ion guide 510 along a straight line, a repulsive voltage is applied to the first transfer electrode 530. For transfer into the second ion guide 520 along path 515, this voltage is switched to attractive one (negative for positive ions). The resulting field extracts ions from the aperture in the first ion guide 510 along DC voltage gradient into the second ion guide 520, where they are captured at the effective potential barrier of the second ion guide 520 and then directed by the DC gradient in the same way as described in the sections above. This process could be also run in gating mode, that is transfer taking place for a short time only, for example for selected species. In this case, rapid switching (or pulsing) of the voltage on transfer electrode 530 from repulsive to attractive and back to repulsive voltage can be used. The transfer electrodes may be referred to herein as gating electrodes in such embodiments.
Referring next to
The second ion guide 620 also has lower voltage offset (for positive ions) than the first ion guide 610. For transmission of ions through the first ion guide 610 on a straight line path, a repulsive voltage is applied to the first transfer electrode 630. For transfer through an aperture 618 in the first ion guide 610 into the second ion guide 620 guide, this voltage is switched to attractive one (negative for positive ions). The resulting field extracts ions along increasing DC voltage gradient created by the second transfer electrode 640. As known in the art, mobility-driven ions are concentrated by electric fields by a ratio equal to the ratio of electric fields. This enables concentration of ions on the narrow entrance of the orthogonal guide and their efficient capture. This could be accompanied by gating.
If a difference in voltage offsets between guides is undesirable and at the same time gating is required, an “energy lift” arrangement could be used as will now be discussed.
Referring next to
The location of the transferred ion packet is shown by a circle and its direction of movement by an arrow. Three effective potential distributions are shown: (a) an initial distribution with ions in first ion guide A1 prior to transfer; (b) ions are transferred to the gap between first and second transfer electrodes (labelled E1 and E2, corresponding respectively to first transfer electrode 530, 630 and second transfer electrode 540, 640 of
Referring next to
This drawing shows an alternative way to allow orthogonal transfer into an asymmetric paired guide. Each of the first ion guide 710 and the second ion guide 720 is suitable for transmitting ions of one type of mobility variance at a given ion charge polarity. In this case, there is no need for spatial focusing: once ions reach the extended open space of the second ion guide 720 on the right, they get captured by DC and RF fields and are transported into the narrow gap of the paired second ion guide 720.
It is important to mention that any of the arrangements discussed herein could be also used to dump unwanted ions into a dump cavity where they could be disposed of without contaminating ion guides. In this case, a dump cavity (for example, a Faraday cage) may replace the second ion guide.
Geometry other than straight planar geometry is feasible. Reference is now made to
After passing through the first ion guide 810, ions are transferred into the second ion guide 820 as described before. To ensure the same drift length (for example, for ion mobility separation inside a set of arrays), the first ion guide 810 and second ion guide 820 could be arranged so that a smaller circle in the first ion guide 810 is followed by a larger circle in the second ion guide 820 and a larger circle in the first ion guide 810 is followed by a smaller circle in the second ion guide 820, summing up to the same length for all ions. This may be effected by transferring ions from the inner channel of the first ion guide 810 to the outer channel of the second ion guide 820, transferring ions from the outer channel of the first ion guide 810 to the inner channel of the second ion guide 820, transferring ions from the inner channel of the second ion guide 820 to the outer channel of the first ion guide 810 and transferring ions from the outer channel of the second ion guide 820 to the inner channel of the first ion guide 810.
Any combination of these elements could be used to create analytical instruments with any number and/or arrangement of stages. The embodiments described in relation to
Similar transfer principles could be also employed in a pulsed manner, especially for injection into other devices such as ion mobility spectrometers, between regions of different pressures or different gases, etc.
Considering a implementation using asymmetric or symmetric sinusoidal voltages, another generalised sense of the disclosure may be considered as an ion optical device, comprising: a first ion repulsive surface; and a second ion repulsive surface, spatially separated from the first ion repulsive surface, so as to define an ion channel between the first and second ion repulsive surfaces. Each of the first and second ion repulsive surfaces comprises: a first plurality of elongated electrodes distributed along an axis, configured to receive a first RF voltage; and a second plurality of elongated electrodes distributed along the axis, the second plurality of electrodes being interleaved with the first plurality of electrodes and configured to receive a second RF voltage, having a different phase than the first RF voltage. In such an aspect, the first and second RF voltages typically have symmetric waveforms. Any of the other features described herein with reference to the ion repulsive surfaces and/or ion optical devices may be applied to this configuration, for example including those discussed in a generalised or specific sense above. Also, ion optical systems using one or more ion optical devices may be considered, as detailed further below.
In accordance with any of the general senses of the disclosure considered above, the ion optical device may further comprise a transport controller, configured to induce movement of ions within the or each ion channel, for instance by controlling one or more of: application of time-invariant potentials to create a steady-state electric field along a length of the or each ion channel (for example, perpendicular to the length direction of the elongate electrodes, that is across the electrode); gas flow along the length of the or each ion channel; and application of travelling wave potentials to create a moving electric field along the length of the or each ion channel. Optionally, the transport controller may be configured to control the application of potentials to one or more of: the first plurality of electrodes; the second plurality of electrodes; and supplementary electrodes each positioned between one of the first plurality of electrodes and one of the second plurality of electrodes. The transport controller may comprise a computer system controlling one of more voltage supplies for application of the time-invariant potentials or travelling wave potentials and/or controlling one or more gas supplies for supplying the gas flow.
One aspect of the disclosure may be found in an ion optical system, comprising an ion optical device, configured to receive ions and as herein described. The ion optical system may further comprise: at least one gating electrode; and a DC power supply, configured selectively to provide a DC potential to the at least one gating electrode, so as to cause transfer of ions from the ion optical device to an output device. The output device may be another (that is, a second) ion optical device, which optionally may be in accordance with those described herein.
In some embodiments (examples of which are shown in
Advantageously, a gating electrode may be positioned on the substrate of an ion repulsive surface of the ion optical device near the aperture. A single gating electrode may be used in some embodiments. In other embodiments, there may be multiple gating electrodes, for example: a first gating electrode, positioned on or adjacent to ion optical device; and a second gating electrode, positioned on or adjacent to the output device. In this case, a first DC gating potential may be provided to the first gating electrode and a second DC gating potential may be provided to the second gating electrode. The first and second DC gating potentials may then be configured to cause ions to travel from the first ion optical device through the aperture and to the second ion optical device.
Where the output device is a second ion optical device, configured to receive ions from the first ion optical device, a number of options may apply. In a first option, the second ion optical device is orientated parallel to the first ion optical device. Then, the first ion optical device may have a first aperture in an ion repulsive surface of the first ion optical device for ions to travel therethrough and the second ion optical device may have a second aperture in an ion repulsive surface of the second ion optical device for ions to be received from the first ion optical device. Alternatively, the second ion optical device may be orientated perpendicular to the first ion optical device. Then, the first ion optical device may have an aperture in an ion repulsive surface of the first ion optical device for ions to travel therethrough and the second ion optical device may be positioned such that ions can travel through the aperture and be received in an end of an ion channel of the second ion optical device (that is between the ion repulsive surfaces of the ion optical device or between an ion repulsive surface and a plate electrode of the ion optical device).
Considering an ion optical system having a plurality of RF ion guides, the plurality of RF ion guides may comprise: a first ion optical device having a first circular axis in a first plane; and a second ion optical device having a second circular axis that has a centre offset from the centre of the first circular axis, such that the first and second circular axes overlap. The second circular axis is beneficially defined in a second plane that is parallel with the first plane. Then, the ion optical system advantageously further comprises ion transfer optics, configured to transfer ions between the first and second ion optical devices in the region in which the first and second circular axes overlap.
In another configuration (an example of which is shown in
For instance in the example shown in
More complex ion optical devices may be formed from two parallel substrates each having an array of strip electrodes that are aligned on the opposing substrates and as such form an array of multipole devices.
In a first example, a two-term cosine voltage waveform is used, as described by equation (6) above and shown in
The RF applied to the electrodes is split into two phases, with a first phase applied to electrodes 1, 3, 5, 7 and a second phase having 180 degrees difference being applied to electrodes 2, 4, 6, 8. The waveform used is the sum of two cosine terms as in equation (6) above, the voltage difference between two electrodes of differing phase is given by equation (9) above. Although the applied voltage waveform is asymmetrical, the voltage difference is a symmetrical waveform.
Referring next to
The symmetrical waveform of the voltage difference created between the electrodes provides an even lower potential barrier than is the case with the sinusoidal waveform (compare
Referring now to
If multiple term cosine waveforms are split into only two different phases, as is proposed in many published documents, the electric field within the structure is greatly reduced for a substantial fraction of the cycle. This is readily appreciated when rectangular waveforms are considered. If a rectangular voltage waveform with ratio 2:1 is used instead of the two-term cosine waveform, for one third of the cycle there is no electric field created within the structure, as all poles are at the same voltage. Similar problems occur when using a 3:1 three-term cosine waveform: if a rectangular voltage waveform is used instead of the three-term cosine waveform, for half the cycle there is no electric field created within the structure, as all poles are at the same voltage.
In a general sense of the disclosure, there may be considered a multipole ion optical device, comprising: a first plurality of electrodes distributed along a first axis (for example, defined by a first substrate); and a second plurality of electrodes distributed along a second axis, generally parallel to the first axis (for example, defined by a second substrate), to define an ion channel between the first and second pluralities of electrodes. For instance, the first and second axes may be defined by respective substrates, upon which the respective plurality of electrodes are provided (or mounted). Each of the first plurality of electrodes and the second plurality of electrodes is configured to receive a respective RF voltage having an asymmetric waveform and such that adjacent electrodes of the first and second pluralities of electrodes receive RF voltages having different phases (“adjacent” in this context advantageously meaning both next to each other within the same plurality of electrodes or next to each other but on different axes). The RF voltages are beneficially multipole potentials. In this way, ions can be trapped in the ion channel, especially by effective potential wells formed by the multipole potentials. Advantageously, the first and second plurality of electrodes and the plurality of RF voltages are configured such to have a high electric field strength in the ion channel, in particular, sufficiently high for ions to experience mobility variation. As discussed above, the minimum field strength for ions to experience mobility variation may depend on the specific configuration, but in some embodiments, this may be achieved by a field strength of at least 104 V/cm or 1 MV/m.
Optionally, a housing encloses the first and second pluralities of electrodes. The environment in which the electrodes are located, for example the housing, is advantageously configured to operate at a gas pressure that is sufficiently high such that, in combination with a frequency of the RF voltages, a phase shift between the electric field and a velocity of ions in the ion channel experiencing the electric field is substantially zero. For example, a gas pressure of at least 10 kPa may be considered in embodiments. Functional operation at atmospheric pressure (or pressures approaching atmospheric) should also be possible. The environment may be air and/or the electrodes or housing may be configured to operate in air. Generally only RF voltages (that is, no DC, such as a FAIMS compensation voltage) are applied to the first and second pluralities of electrodes.
The RF voltages having asymmetric waveforms (typically the same waveform with different phases) may have a ratio of a positive peak voltage to a negative peak voltage (or a ratio of a negative peak voltage to a positive peak) with a magnitude of at least 2. Typically, this ratio is an integer.
In preferred embodiments, each of the first plurality of electrodes are equally axially spaced along the first axis and each of the second plurality of electrodes are equally axially spaced along the second axis. The equal spacing between electrodes may improve the quality of the effective potential well.
In one example, the first plurality of electrodes comprises: a first electrode; and a fourth electrode, adjacent the first electrode, and the second plurality of electrodes comprises: a second electrode, generally opposite (and aligned with) the first electrode; and a third electrode, adjacent the second electrode and generally opposite (and aligned with) the fourth electrode. A first RF voltage, having an asymmetric waveform and a RF frequency may be applied to the first electrode and the third electrode. A second RF voltage having an asymmetric waveform and the RF frequency may be applied to the second electrode and the fourth electrode. A phase difference between the first RF voltage and the second RF voltage is approximately π (180 degrees).
The first and second pluralities of electrodes are advantageously configured in groups of a fixed number of adjacent of electrodes (“adjacent” in this context again meaning both next to each other within the same plurality of electrodes or next to each other but on different axes). The fixed number of electrodes in each group are beneficially configured to receive multipole RF voltages, such that adjacent electrodes within the group (and more preferably, between groups) receive RF voltages of the same frequency and having a phase differing by 2π divided by the fixed number. Thus, working clockwise around a group of the first and second pluralities of electrodes within the ion optical device, the phase of the RF voltage applied should differ by the same amount between each electrode, the phase difference between the last electrode and first electrode also being that same amount. Quadrupole and tripole examples of this configuration will now be discussed in specific terms, with a summary in these more general terms being provided thereafter.
A quadrupole example will first be discussed. According to this one embodiment of the present disclosure, the multiple-term cosine asymmetrical voltage waveform applied to the electrodes is split into four phases, each being 90 degrees (π/2 radians) apart. The waveform is split into four different phases and one phase applied to each of the first four electrodes and to each of the second group of four electrodes. Referring to
Referring now to
This shows that ion motion is rotational. Comparison with
Next, referring to
Each group of four electrodes possesses a potential well and a barrier exists for the type C ions, which can be made far greater than may be overcome by any significant number of ions simply by diffusion at room temperature. The proportion of ions that might exceed the barrier due to diffusion at a given effective temperature can be estimated using the Maxwell-Boltzmann probability density function. Given the model of the strip electrode structure, well inside the structure away from the edges where no electric fields exist in the z direction, the effective temperature of ions held within the effective potential wells can be derived from the velocity distribution in the z direction, when the simulation includes calculating individual random elastic collisions. Ions obtain kinetic energy in the z direction due to the random impact parameter and have a Gaussian velocity distribution from which the effective temperature can be derived.
Examination of
Referring next to
Use of the four-fold phase split changes the effective potential within the structure. Now, type A ions and type C ions experience opposite net displacements over each cycle and where for the type C ion there is an effective potential well in the centre of each group of four electrodes, for ions of type A there is a potential hill. The magnitude of the well for type C low mass ions (100 Da) is about an order of magnitude larger than that obtained with the two-fold phase split (compare
Whilst the electrode structure is not wholly symmetrical, being formed of electrodes on two substrates which lie in the x-z plane, nevertheless the effective potential along the two orthogonal test lines indicates that the effective potential is very similar for the geometry considered here.
If the positive polarity voltage waveform is used (
Referring next to
It is noted that the mobility-invariant ion (c) shows the pseudo-potential effect only, which is the same regardless of the polarity of the waveform (compare positive and negative waveforms in
Traps operating with the differential mobility effect described above can only trap either type A ions (positive polarity) or type C ions (negative polarity). However, by operating electrodes 1, 2, 3, 4 in one polarity, and 5, 6, 7, 8 in the opposite polarity, adjacent traps will confine the different mobility variant ions.
With this is mind, reference is now made to
Referring next to
It can be seen that electrodes 1-4 trap ions of type C mobility variance and electrodes 5-8 trap ions of type A mobility variance. Directing a source of ions into the strip electrode structure in the z direction—along the strips—will result in ions of type A and type C differential mobility being confined in those traps that have an effective potential well for that type of ion mobility. The trapping potential (effective potential) is far greater than that produced by existing methods that utilise the pseudo-potential effect only. A modest well exists for all ions between electrodes 3, 4, 5 and 6 (in the region of x=0). However at room temperature, diffusion can cause ions to exceed the barrier and ions may move to the location between electrodes 1-4 if the ions have type C mobility variance and between electrodes 5-8 if the ions have type A mobility variance.
Although two-term cosine voltage waveforms have been discussed above, voltage waveforms based on more than two cosine terms. For example, a 3:1 three-term cosine voltage waveform described by equation (7a) above can also be applied to embodiments according to the present disclosure.
Referring next to
Referring next to
The array of strip electrodes having 4-fold phase splitting of the applied voltage waveform forms a set of traps. Traps are formed with asymmetric voltage waveforms having a ratio of peak voltages at opposite polarities which is not equal to one. Ratios of 2:1 and 3:1 have been illustrated here but other ratios may be used with such embodiments.
Returning to the general terms considered above, in one example (of quadrupole ion optical device), the first plurality of electrodes comprises: a first electrode; and a fourth electrode, adjacent the first electrode, and the second plurality of electrodes comprises: a second electrode, generally opposite (and aligned with) the first electrode; and a third electrode, adjacent the second electrode and generally opposite (and aligned with) the fourth electrode. A first RF voltage, having an asymmetric waveform and a RF frequency is applied to the first electrode. A second RF voltage having an asymmetric waveform and the RF frequency is applied to the second electrode, a phase difference between the first RF voltage and the second RF voltage being approximately π/2 (90 degrees). A third RF voltage, having an asymmetric waveform and the RF frequency is applied to the third electrode, a phase difference between the second RF voltage and the third RF voltage being approximately π/2. A fourth RF voltage having an asymmetric waveform and the RF frequency is applied to the fourth electrode, a phase difference between the third RF voltage and the fourth RF voltage being approximately π/2. Hence, a phase difference between the fourth RF voltage and the first RF voltage is also approximately π/2.
Optionally, the first plurality of electrodes further comprises a fifth electrode, adjacent the fourth electrode, the first RF voltage being applied to the fifth electrode, and the second plurality of electrodes further comprises a sixth electrode, adjacent the third electrode and generally opposite the fifth electrode, the second RF voltage being applied to the sixth electrode.
More generally, the first, second, third and fourth electrodes may define an electrode unit. Then, the electrode unit may be repeated along the first and second axes. Arrays of quadrupole traps may thereby be formed.
In one embodiment, the first, second, third and fourth electrodes define a first electrode unit and the RF voltages applied to the first electrode unit have a first polarity (in the sense of the polarity of the average voltage over a cycle of the waveform). Then, a second electrode unit may be provided adjacent the first electrode unit along the first and second axes. The second electrode unit is advantageously essentially identical to the first electrode unit except that the RF voltages applied to the second electrode unit have a second polarity that is opposite the first polarity. This may allow trapping of ions of different mobility variation type.
This may be applied more generally considering where the first and second pluralities of electrodes are configured in groups of a fixed number of adjacent electrodes, this fixed number of adjacent electrodes defining an electrode unit, which may be repeated. Optionally, a polarity of the RF voltages applied to one electrode unit may differ from a polarity of the RF voltages applied to another electrode unit, for example to allow trapping of ions of different mobility variation type.
Another example of a tripole ion optical device may be considered. For instance, the first plurality of electrodes may comprise: a first electrode; and a third electrode, adjacent the first electrode. The second plurality of electrodes may comprise a second electrode, opposite and axially between the first and third electrodes. Then, a first RF voltage, having an asymmetric waveform and a RF frequency may be applied to the first electrode, a second RF voltage having an asymmetric waveform and the RF frequency may be applied to the second electrode and a third RF voltage having an asymmetric waveform and the RF frequency may be applied to the third electrode. Advantageously, a phase difference between the first RF voltage and the second RF voltage is approximately 2π/3 (120 degrees) and a phase difference between the second RF voltage and the third RF voltage is approximately 2π/3. Thereby, a phase difference between the first RF voltage and the third RF voltage is beneficially also approximately 2π/3.
As identified above, the tripole electrode unit may be repeated. However, the RF voltages applied between groups of three electrodes may need to be reversed for an adjacent group of three electrodes. For instance, the first plurality of electrodes may further comprise: a fifth electrode, adjacent the third electrode and having the second RF voltage applied, the second plurality of electrodes may comprise: a fourth electrode, adjacent the second electrode, opposite and axially between the third and fifth electrodes and having the first RF voltage applied; and a sixth electrode, adjacent the fourth electrode, axially displaced from the fifth electrode away from the fourth electrode and having the third RF voltage applied. Alternatively, it may be considered that the first, second, third, fourth, fifth and sixth electrodes define an electrode unit. Then, the electrode unit may be repeated along the first and second axes, in particular with approximately equal axial spacing between all electrodes.
This general sense will be discussed again below. First, more discussion of specific practical embodiments will be provided.
Ions can be induced to move across an array of traps by the application of a steady-state electric field created by biasing electrodes with time-invariant voltages of increasing magnitude along the array. Additionally or alternatively, a gas flow through the array may be used. In another approach (combinable with those previously described), a time-varying set of voltages may be applied to the trap electrodes and/or one or more supplementary electrodes to produce a travelling wave that creates an electric field which moves across the array, as is known and is for example described in U.S. Pat. No. 9,978,572 B2. As noted above, if a gas flow is used, ions may be retained within the same trap, the gas flow being directed in the z direction, parallel to the elongation of the trap electrodes. Alternatively, the gas flow may be at some other angle to the z axis, including perpendicular to it (that is, in the x direction). A controller may be used to effect transport of ions using any one or combination of these techniques.
In a first example, ions can be induced to move across the array of traps by the application of a steady-state electric field created by biasing electrodes (preferably to the same electrodes to which the RF is applied, but one or more supplementary electrodes can be used instead or in addition) with time-invariant voltages of increasing or decreasing magnitude across the array. Reference is now made to
The time-invariant voltages create a net field along the channel, which is termed herein as an axial field. With no time varying field applied, even if the voltage offset between adjacent electrodes on both substrates is constant, the axial field will not be constant along the array as the width (in x) of the electrodes is the same or similar to the gap between electrodes (in x). The field strength is larger adjacent a gap and smaller adjacent an electrode.
The field strength in x on the axis (y=0) follows an oscillating profile somewhat similar to a sinusoid. The field strength parallel to the axis but displaced by 10 μm (y=10 μm) has a slightly distorted profile. Of course, it is not essential that the electrode width is equal to the gap width and the profile of the oscillating axial field need not be sinusoidal. A non-zero axial electric field along the channel between the substrates is highly desirable though.
When the time varying (RF) voltages are applied, as well as the time-invariant voltages, the traps are formed and the axial field changes with time. Ions can receive a net axial motion under some conditions. Ions are driven across the array if the time-invariant axial field created by the time-invariant voltages is sufficient to drive the ions over the effective potential barriers between the traps. The trapping in the perpendicular direction (y) keeps the ions from striking the electrodes.
Due to the difference in the depth of the effective potential wells (as shown in
Referring to
Referring now to
At low fields low mass or high mobility ions cannot escape the axial traps and are not driven across the array along the axis, whilst high mass or low mobility ions escape the traps and receive a net axial velocity in the ion channel between the substrates (see
At higher axial fields, all ions can escape the traps and low mass or high mobility ions are driven across the array with a higher net axial velocity than the high mass or low mobility ions, and the array of traps forms an ion mobility drift tube (see
As a second example, ions may be driven across the array of traps with the use of an axial gas flow. In a first case, a gas velocity of 25 m/s in the positive x direction is considered, causing ions to move from left to right through the array, moving from trap to trap. Referring to
A gas flow rate of less than some 22 m/s appears to be insufficient to carry the mass 100 Da ion over the barrier of the first trapping region but higher mass ions can escape. For lower gas flows, the minimum mass transmitted is higher. At 10 m/s flow velocity, 330 Da ions and above escape the trap and progress across the array; lower masses remain trapped. If the gas flow velocity is increased to 22 m/s, ions of mass 100 Da and above have sufficiently large collision cross sections that they may escape the effective potential well. The ions progress along the tube with different velocities.
Referring now to
Embodiments of the present disclosure function as described above to form traps for ions within cells comprising sets of four strip electrodes. By displacing one substrate with respect to the other by half the length of one cell in the x direction, sets of tripole traps may be constructed. Similar electrode structures as described above, fabricated using MEMS technology, may be utilised. A straightforward shift of one substrate with respect to the other is required and a different allocation of voltages. The voltage waveform is preferably split into three phases, one phase applied to each electrode of each cell. Referring to
Referring next to
Reference is now made to
Referring next to
Now, referring to
Examination of
Three mobility types are considered: (a) type C ions (solid line); (b) type A ions (dashed line); and (c) mobility invariant ions (dotted line). Using this approximate method, the bottom of the well appears to be offset by approximately 14 μm in γ. A well of some 2.5 V is formed for these ions.
As noted above, ions can be induced to move across the array of traps in a number of different ways. Firstly, by the application of a steady-state electric field created by biasing electrodes with time-invariant voltages of increasing or decreasing magnitude along the array. Alternatively, a gas flow through the array may be used to drive ions either along the array or across the array, or some combination of the two. In a third option, a time-varying set of voltages may be applied to the trap electrodes and/or one or more supplementary electrodes to produce a travelling wave to create an electric field that moves across the array. These can also be applied to tripole-based traps.
With reference to
In this example, under the action of a gas flow velocity of 20 m/s in the positive x direction, ions move from left to right across the array, seemingly finding the path of least resistance, moving from trap to trap. A gas flow rate of less than some 19 m/s appears insufficient to carry the mass 100 Da ion over the barrier of the first trapping region but higher mass ions can escape. For lower gas flows, the minimum mass transmitted appears to be higher. At 10 m/s gas flow velocity, ions of masses equal to and greater than mass of approximately 250 Da can escape the trap and progress across the array. If the gas flow velocity is increased to 19 m/s, mass 100 Da ions may escape the effective potential well. The ions progress across the array with different velocities.
Referring now to
At an increased gas flow of 25 m/s the difference in axial velocities for different mass ions reduces somewhat. With reference to
Referring next to
Other multipoles may be used for the present disclosure and whilst quadrupole and tripole trap structures have been described in some detail, the skilled person can readily extend the treatment to other multipole arrangements.
Returning again to general senses of the disclosure considered above, it may be understood that the first and second pluralities of electrodes define at least one ion trap. Then, the multipole ion optical device may further comprise an ion transport controller, configured to induce the movement of ions trapped in the at least one ion trap. For instance, the ion transport controller may be configured to induce the movement of ions trapped in the at least one ion trap by one or more of: a) applying a steady-state electric field to the at least one ion trap first and/or second pluralities of electrodes, by biasing the first and/or second pluralities of electrodes and/or one or more supplementary electrodes with time-invariant voltages to generate a voltage gradient (for instance, voltages of increasing or decreasing magnitude) along the first and/or second axis; b) causing a gas to flow through the array (ion channel); and c) applying a time-varying set of voltages to the first and/or second pluralities of electrodes and/or one or more supplementary electrodes to produce a travelling wave, such than an electric field is caused that moves across the first and/or second axis. Using any of these techniques (alone or in combination), the ion transport controller may be configured to induce the movement of ions trapped in the at least one ion trap in a direction parallel to the first axis and/or the second axis. This may also allow separation of ions according to their mass and/or mobility (or mobility type). Applying a time-invariant bias voltage to the first and/or second pluralities of electrodes of a predetermined voltage may allow the ion transport controller to separate of ions by their mass and/or mobility.
The use of gas flow may be advantageous in other ways. For example, the ion transport controller may be configured to induce the movement of ions trapped in the at least one ion trap in a direction perpendicular to the first axis and the second axis, by causing a gas to flow through the array. In embodiments, the ion transport controller is configured to separate ions according to their mass and/or mobility, by causing a gas to flow through the array at a predetermined flow rate.
The use of one or more multipole ion optical devices in accordance with the present disclosure may allow sophisticated instruments, for example, a mass spectrometer or ion mobility spectrometer, comprising such a multipole ion optical device may be considered. In embodiments, the multipole ion optical device is configured to act as one or more of: a mass filter; a mass analyser; an ion mobility filter; an ion mobility analyser; and a drift tube.
Although embodiments according to the disclosure have been described with reference to particular types of devices and applications (particularly mass spectrometers and/or ion mobility spectrometers) and the embodiments have particular advantages in such case, as discussed herein, approaches according to the disclosure may be applied to other types of device and/or application. The specific manufacturing details of the ion repulsive surface, ion optical device (such as ion guide), ion optical system and associated uses, whilst potentially advantageous (especially in view of known manufacturing constraints and capabilities), may be varied significantly to arrive at devices with similar or identical operation. Each feature disclosed in this specification, unless stated otherwise, may be replaced by alternative features serving the same, equivalent or similar purpose. Thus, unless stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.
The methods and apparatus of the present disclosure can be utilised with a variety of electrode structures. Strip electrodes have been used in examples above, but the present disclosure is not limited to the use of such elongated linear electrodes. Electrodes of appropriate dimensions can be arranged into symmetrical or asymmetrical patterns upon substrates and if elongation of electrodes is beneficial for a particular application, the electrodes may be linear or curving. Individual electrodes can be hemispherical, rectangular or of other shapes. The presence of a substrate is not essential for working the invention. The strip electrodes may be supported in other ways, for example held at their ends by electrically-insulating supports. The substrate, if present, can be planar or can have a non-planar surface upon which electrodes are arranged. The substrates could comprise two concentric cylinders, with one or both of the curved surfaces facing each other having an array of elongated electrodes located on them. The cylinders can be considered as equivalent to the planar substrates described above but rolled-up. The elongated electrodes may be annular in such embodiments using cylinders. One of the cylinders could be a DC only electrode, with a function similar to the flat plate electrode in the embodiments described above. In some embodiments using two concentric cylinders as substrates, a third cylinder may be located between them, which could have a DC voltage only applied, analogous to the planar structure shown in
At atmospheric pressure in air it is advantageous to utilise electrodes having characteristic dimension (width and/or height) of ten or a few tens of microns, and to have similar sized or preferably slightly smaller gaps between adjacent electrodes which are to have a different phase and/or polarity of voltage applied to them. The field strength which can be obtained before breakdown increases rapidly as the distance between electrodes is reduced. A higher field strength causes ions to reach the higher velocities over parts of the oscillation cycle which enables the differential mobility effect to be utilised. Preferably the strip electrodes are somewhat wider in x than are the gaps between adjacent electrodes in x and at atmospheric pressure in air, a favourable x width of 30 μm with 15 μm gaps is a preferable combination. More generally, a width of the electrode (in the x dimension) may be from 10 μm to 50 μm and more preferably from 20 μm to 40 μm and/or the ratio of electrode width to gap is preferably 1 to 3, more preferably 1.5 to 2.5 and advantageously approximately 2. Such configurations may be provided in conjunction with a flat plate electrode preferably situated at a distance from strip electrodes that is 2-5 times (or 3-4 times) the width of the strip electrodes, for instance about 100 μm from the outer face of the strip electrodes. The base frequency of the voltage drive (the frequency of the largest cosine component) is preferably 20-80 MHz and the voltage 150-200 V (zero-to-peak). Reducing the width of the ion channel may require higher voltage drive frequency so that ion oscillation amplitudes do not become a substantial fraction of the ion channel width.
Preferably, where there is a substrate, the strip electrodes are wider (in x) than any underlying raised portion of the substrate, so that the conductive strips overhang the substrate. Examples of such overhanging electrodes on a substrate are described in WO2014/048837 A2. In another embodiment, the strip electrodes are manufactured to be the full height from a planar substrate surface, as has been the case in the simulations described above.
Ions can be induced to move within the ion channel by the application of a steady-state electric field created by biasing electrodes with time-invariant voltages of increasing or decreasing magnitude along the array. Alternatively or additionally, a gas flow through the array (ion channel) may be used or a time-varying set of voltages may be applied to the array electrodes to produce a travelling wave, which creates an electric field which moves along the array, as is known and is for example described in U.S. Pat. No. 9,978,572 B2. If a gas flow is used, ions may be retained between the same elongated electrodes, the gas flow being directed in the z direction, parallel to the elongation of the array electrodes. Alternatively, the gas flow may be at some other angle to the z axis, including perpendicular to it (that is, in the x direction). If a static distribution of time-invariant voltages is used to create an electric field across the ion channel in the x direction, the time-invariant voltages may be applied as offsets to the RF potentials provided to the strip electrodes. This is a relatively simple approach, but over extended lengths, it can result in an impractically large voltage drop across the array. The travelling wave approach requires a more sophisticated control, but it avoids the voltage build-up problem. An alternative implementation is to provide supplementary electrodes situated in the bottom of the troughs, which are aligned to drive ions along the x or z direction. Where either a steady-state electric field or a travelling wave electric field is used to drive ions within the ion channel, a gas flow may be provided that flows in a direction counter to the direction in which the ions are driven by the electric field. Such counter gas flow configurations may be used for ion mobility separation of ions within the ion channel.
As used herein, including in the claims, unless the context indicates otherwise, singular forms of the terms herein are to be construed as including the plural form and vice versa. For instance, unless the context indicates otherwise, a singular reference herein including in the claims, such as “a” or “an” (such as an analogue to digital convertor) means “one or more” (for instance, one or more analogue to digital convertor). Throughout the description and claims of this disclosure, the words “comprise”, “including”, “having” and “contain” and variations of the words, for example “comprising” and “comprises” or similar, mean “including but not limited to”, and are not intended to (and do not) exclude other components.
The use of any and all examples, or exemplary language (“for instance”, “such as”, “for example” and like language) provided herein, is intended merely to better illustrate the invention and does not indicate a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention.
Any steps described in this specification may be performed in any order or simultaneously unless stated or the context requires otherwise.
All of the aspects and/or features disclosed in this specification may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive. As described herein, there may be particular combinations of aspects that are of further benefit, such the aspects of ion guides for use in mass spectrometers and/or ion mobility spectrometers. In particular, the preferred features of the invention are applicable to all aspects of the invention and may be used in any combination. Likewise, features described in non-essential combinations may be used separately (not in combination).
Number | Date | Country | Kind |
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2102365.0 | Feb 2021 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/054097 | 2/18/2022 | WO |