This invention relates to the field of mass spectrometry, in particular high mass resolution time-of-flight mass spectrometry and electrostatic trap mass spectrometry utilizing multi-reflection techniques for extending the ion flight path.
Various arrangements utilizing multi-reflection to extend the flight path of ions within mass spectrometers are known. Flight path extension is desirable to increase time-of-flight separation of ions within time-of-flight (TOF) mass spectrometers or to increase the trapping time of ions within electrostatic trap (EST) mass spectrometers. In both cases the ability to distinguish small mass differences between ions is thereby improved.
An arrangement of two parallel opposing mirrors was described by Nazarenko et. al. in patent SU1725289. These mirrors were elongated in a drift direction and ions followed a zigzag flight path, reflecting between the mirrors and at the same time drifting relatively slowly along the extended length of the mirrors in the drift direction. Each mirror was made of parallel bar electrodes. The number of reflection cycles and the mass resolution achieved were able to be adjusted by altering the ion injection angle. The design was advantageously simple in that only two mirror structures needed to be produced and aligned to one another. However this system lacked any means to prevent beam divergence in the drift direction. Due to the initial angular spread of the injected ions, after multiple reflections the beam width may exceed the width of the detector making any further increase of the ion flight time impractical due to the loss of sensitivity. Ion beam divergence is especially disadvantageous if trajectories of ions that have undergone a different number of reflections overlap, thus making it impossible to detect only ions having undergone a given number of oscillations. As a result, the design has a limited angular acceptance and/or limited maximum number of reflections. Furthermore, the ion mirrors did not provide time-of-flight focusing with respect to the initial ion beam spread across the plane of the folded path, resulting in degraded time-of-flight resolution for a wide initial beam angular divergence.
Wollnik, in GB patent 2080021, described various arrangements of parallel opposing gridless ion mirrors. Two rows of mirrors in a linear arrangement and two opposing rings of mirrors were described. Some of the mirrors may be tilted to effect beam injection. Each mirror was rotationally symmetric and was designed to produce spatial focusing characteristics so as to control the beam divergence at each reflection, thereby enabling a longer flight path to be obtained with low beam losses. However these arrangements were complex to manufacture, being composed of multiple high-tolerance mirrors that required precise alignment with one another. The number of reflections as the ions passed once through the analyser was fixed by the number of mirrors and could not be altered.
Su described a gridded parallel plate mirror arrangement elongated in a drift direction, in International Journal of Mass Spectrometry and Ion Processes, 88 (1989) 21-28. The opposing ion reflectors were arranged to be parallel to each other and ions followed a zigzag flight path for a number of reflections before reaching a detector. The system had no means for controlling beam divergence in the drift direction, and this, together with the use of gridded mirrors which reduced the ion flux at each reflection, limited the useful number of reflections and hence flight path length.
Verentchikov, in WO2005/001878 and GB2403063 described the use of periodically spaced lenses located within the field free region between two parallel elongated opposing mirrors. The purpose of the lenses was to control the beam divergence in the drift direction after each reflection, thereby enabling a longer flight path to be advantageously obtained over the elongated mirror structures described by Nazarenko at al. and Su. To further increase the path length, it was proposed that a deflector be placed at the distal end of the mirror structure from the ion injector, so that the ions may be deflected back through the mirror structure, doubling the flight path length. However the use of a deflector in this way is prone to introducing beam aberrations which would ultimately limit the maximum resolving power that could be obtained. In this arrangement the number of reflections is set by the position of the lenses and there is not the possibility to change the number of reflections and thereby the flight path length by altering the ion injection angle. The construction is also complex, requiring precise alignment of the multiple lenses. Lenses and the end deflector are furthermore known to introduce beam aberrations and ultimately this placed limits on the types of injection devices that could be used and reduced the overall acceptance of the analyser. In addition, the beam remains tightly focused over the entire path making it more susceptible to space charge effects.
Makarov et. al., in WO2009/081143, described a further method of introducing beam focusing in the drift direction for a multi-reflection elongated TOF mirror analyser. Here, a first gridless elongated mirror was opposed by a set of individual gridless mirrors elongated in a perpendicular direction, set side by side along the drift direction parallel to the first elongated mirror. The individual mirrors provided beam focusing in the drift direction. Again in this arrangement the number of beam oscillations within the device is set by the number of individual mirrors and cannot be adjusted by altering the beam injection angle. Whilst less complex than the arrangement of Wollnik and that of Verentchikov, nevertheless this construction is more complex than the arrangement of Nazarenko et. al. and that of Su.
Golikov, in WO2009001909, described two asymmetrical opposed mirrors, arranged parallel to one another. In this arrangement the mirrors, whilst not rotationally symmetric, did not extend in a drift direction and the mass analyzer typically has a narrow mass range because the ion trajectories spatially overlap on different oscillations and cannot be separated. The use of image current detection was proposed.
A further proposal for providing beam focusing in the drift direction in a system comprising elongated parallel opposing mirrors was provided by Verentchikov and Yavor in WO2010/008386. In this arrangement periodic lenses were introduced into one or both the opposing mirrors by periodically modulating the electric field within one or both the mirrors at set spacings along the elongated mirror structures. Again in this construction the number of beam oscillations cannot be altered by changing the beam injection angle, as the beam must be precisely aligned with the modulations in one or both the mirrors. Each mirror is somewhat more complex in construction than the simple planar mirrors proposed by Nazarenko et. al.
A somewhat related approach was proposed by Ristroph et. al. in US2011/0168880. Opposing elongated ion mirrors comprise mirror unit cells, each having curved sections to provide focusing in the drift direction and to compensate partially or fully for a second order time-of-flight aberration with respect to the drift direction. In common with other arrangements, the number of beam oscillations cannot be altered by changing the beam injection angle, as the beam must be precisely aligned with the unit cells. Again the mirror construction is more complex than that of Nazarenko et. al.
All arrangements which maintain the ions in a narrow beam in the drift direction with the use of periodic structures necessarily suffer from the effects of space-charge repulsion between ions.
Sudakov, in WO2008/047891, proposed an alternative means for both doubling the flight path length by returning ions back along the drift length and at the same time inducing beam convergence in the drift direction. In this arrangement the two parallel gridless mirrors further comprise a third mirror oriented perpendicularly to the opposing mirrors and located at the distal end of the opposing mirrors from the ion injector. The ions are allowed to diverge in the drift direction as they proceed through the analyser from the ion injector, but the third ion mirror reverts this divergence and, after reflection in the third mirror, upon arriving back in the vicinity of the ion injector the ions are once again converged in the drift direction. This advantageously allows the ion beam to be spread out in space throughout most of its journey through the analyser, reducing space charge interactions, as well as avoiding the use of multiple periodic structures along or between the mirrors for ion focusing. The third mirror also induces spatial focussing with respect to initial ion energy in the drift direction. There being no individual lenses or mirror cells, the number of reflections can be set by the injection angle. However, the third mirror is necessarily built into the structure of the two opposing elongated mirrors and effectively sections the elongated mirrors, i.e. the elongated mirrors are no longer continuous—and nor is the third mirror. This has the disadvantageous effect of inducing a discontinuous returning force upon the ions due to the step-wise change in the electric field in the gaps between the sections. This is particularly significant since the sections occur near the turning point in the drift direction where the ion beam width is at its maximum. This can lead to uncontrolled ion scattering and differing flight times for ions reflected within more than one section during a single oscillation.
In view of the above, the present invention has been made.
According to an aspect of the present invention there is provided a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, characterized in that the mirrors are not a constant distance from each other in the X direction along at least a portion of their lengths in the drift direction.
According to a further aspect of the present invention there is provided a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, characterized in that the mirrors are inclined to one other in the X direction along at least a portion of their lengths in the drift direction.
According to a further aspect of the present invention there is provided a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, characterized in that the mirrors converge towards each other in the X direction along at least a portion of their lengths in the drift direction.
The present invention further provides a method of mass spectrometry comprising the steps of injecting ions into a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, characterized in that the mirrors are not a constant distance from each other in the X direction along at least a portion of their lengths in the drift direction; and detecting at least some of the ions during or after their passage through the mass spectrometer.
The present invention further provides a method of mass spectrometry comprising the steps of injecting ions into a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, characterized in that the mirrors are inclined to one other in the X direction along at least a portion of their lengths in the drift direction; and detecting at least some of the ions during or after their passage through the mass spectrometer.
The present invention further provides a method of mass spectrometry comprising the steps of injecting ions into a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, characterized in that the mirrors converge towards each other in the X direction along at least a portion of their lengths in the drift direction; and detecting at least some of the ions during or after their passage through the mass spectrometer.
Preferably, methods of mass spectrometry using the present invention further comprise injecting ions into the multi-reflection mass spectrometer from one end of the opposing ion-optical mirrors in the drift direction and the ion-optical mirrors are closer together in the X direction along at least a portion of their lengths as they extend in the drift direction away from the location of ion injection.
For convenience herein, the drift direction shall be termed the Y direction, the opposing mirrors are set apart from one another by a distance in what shall be termed the X direction, the X direction being orthogonal to the Y direction, this distance varying at different locations in the Y direction as described above. The ion flight path generally occupies a volume of space which extends in the X and Y directions, the ions reflecting between the opposing mirrors and at the same time progressing along the drift direction Y. The mirrors generally being of smaller dimensions in the perpendicular Z direction, the volume of space occupied by the ion flight path is a slightly distorted rectangular parallelepiped with a smallest dimension preferably being in the Z direction. For convenience of the description herein, ions are injected into the mass spectrometer with initial components of velocity in the +X and +Y directions, progressing initially towards a first ion-optical mirror located in a +X direction and along the drift length in a +Y direction. The average component of velocity in the Z direction is preferably zero.
The ion optical mirrors oppose one another. By opposing mirrors it is meant that the mirrors are oriented so that ions directed into a first mirror are reflected out of the first mirror towards a second mirror and ions entering the second mirror are reflected out of the second mirror towards the first mirror. The opposing mirrors therefore have components of electric field which are generally oriented in opposite directions and facing one another.
The multi-reflection mass spectrometer comprises two ion-optical mirrors, each mirror elongated predominantly in one direction. The elongation may be linear (i.e. straight), or the elongation may be non-linear (e.g. curved or comprising a series of small steps so as to approximate a curve), as will be further described. The elongation shape of each mirror may be the same or it may be different. Preferably the elongation shape for each mirror is the same. Preferably the mirrors are a pair of symmetrical mirrors. Where the elongation is linear, in some embodiments of the present invention, the mirrors are not parallel to each other. Where the elongation is non-linear, in some embodiments of the present invention at least one mirror curves towards the other mirror along at least a portion of its length in the drift direction.
The mirrors may be of any known type of elongated ion mirror. In embodiments where the one or both elongated mirrors is curved, the basic design of known elongated ion mirrors may be adapted to produce the required curved mirror. The mirrors may be gridded or the mirrors may be gridless. Preferably the mirrors are gridless.
As herein described, the two mirrors are aligned to one another so that they lie in the X-Y plane and so that the elongated dimensions of both mirrors lie generally in the drift direction Y. The mirrors are spaced apart and oppose one another in the X direction. However, in some embodiments, as the distance or gap between the mirrors is arranged to vary as a function of the drift distance, i.e. as a function of Y, the elongated dimensions of both mirrors will not lie precisely in the Y direction and for this reason the mirrors are described as being elongated generally along the drift direction Y. In these embodiments the elongated dimension of at least one mirror will be at an angle to the Y direction for at least a portion of its length. Preferably the elongated dimension of both mirrors will be at an angle to the Y direction for at least a portion of its length.
Herein, in both the description and the claims, the distance between the opposing ion-optical mirrors in the X direction means the distance between the average turning points of ions within those mirrors at a given position along the drift length Y. A precise definition of the effective distance L between the mirrors that have a field-free region between them (where that is the case), is the product of the average ion velocity in the field-free region and the time lapse between two consecutive turning points. An average turning point of ions within a mirror herein means the maximum distance in the +/−X direction within the mirror that ions having average kinetic energy and average initial angular divergence characteristics reach, i.e. the point at which such ions are turned around in the X direction before proceeding back out of the mirror. Ions having a given kinetic energy in the +/−X direction are turned around at an equipotential surface within the mirror. The locus of such points at all positions along the drift direction of a particular mirror defines the turning points for that mirror, and the locus is hereinafter termed an average reflection surface. Therefore the variation in distance between the opposing ion-optical mirrors is defined by the variation in distance between the opposing average reflection surfaces of the mirrors. In both the description and claims reference to the distance between the opposing ion-optical mirrors is intended to mean the distance between the opposing average reflection surfaces of the mirrors as just defined. In the present invention, immediately before the ions enter each of the opposing mirrors at any point along the elongated length of the mirrors they possess their original kinetic energy in the +/−X direction. The distance between the opposing ion-optical mirrors may therefore also be defined as the distance between opposing equipotential surfaces where the nominal ions (those having average kinetic energy and average initial angular incidence) turn in the X direction, the said equipotential surfaces extending along the elongated length of the mirrors.
In the present invention, the mechanical construction of the mirrors themselves may appear, under superficial inspection, to maintain a constant distance apart in X as a function of Y, whilst the average reflection surfaces may actually be at differing distances apart in X as a function of Y. For example, one or more of the opposing ion-optical mirrors may be formed from conductive tracks disposed upon an insulating former (such as a printed circuit board) and the former of one such mirror may be arranged a constant distance apart from an opposing mirror along the whole of the drift length whilst the conductive tracks disposed upon the former may not be a constant distance from electrodes in the opposing mirror. Even if electrodes of both mirrors are arranged a constant distance apart along the whole drift length, different electrodes may be biased with different electrical potentials within one or both mirrors along the drift lengths, causing the distance between the opposing average reflection surfaces of the mirrors to vary along the drift length. Thus, the distance between the opposing ion-optical mirrors in the X direction varies along at least a portion of the length of the mirrors in the drift direction.
Preferably the variation in distance between the opposing ion-optical mirrors in the X direction varies smoothly as a function of the drift distance. In some embodiments of the present invention the variation in distance between the opposing ion-optical mirrors in the X direction varies linearly as a function of the drift distance. In some embodiments of the present invention the variation in distance between the opposing ion-optical mirrors in the X direction varies non-linearly as a function of the drift distance.
In some embodiments of the present invention the opposing mirrors are elongated linearly generally in the drift direction and are not parallel to each other (i.e. they are inclined to one another along their whole length) and in such embodiments the variation in distance between the opposing ion-optical mirrors in the X direction varies linearly as a function of the drift distance. In a preferred embodiment the two mirrors are further apart from each other at one end, that end being in a region adjacent an ion injector, i.e. the elongated ion-optical mirrors are closer together in the X direction along at least a portion of their lengths as they extend in the drift direction away from the ion injector. In some embodiments of the present invention at least one mirror and preferably each mirror curves towards or away from the other mirror along at least a portion of its length in the drift direction and in such embodiments the variation in distance between the opposing ion-optical mirrors in the X direction varies non-linearly as a function of the drift distance. In a preferred embodiment both mirrors are shaped so as to produce a curved reflection surface, that reflection surface following a parabolic shape so as to curve towards each other as they extend in the drift direction away from the location of an ion injector. In such embodiments the two mirrors are therefore further apart from each other at one end, in a region adjacent an ion injector. Some embodiments of the present invention provide the advantages that both an extended flight path length and spatial focusing of ions in the drift (Y) direction is accomplished by use of non-parallel mirrors. Such embodiments advantageously need no additional components to both double the drift length by causing ions to turn around and proceed back along the drift direction (i.e. travelling in the −Y direction) towards an ion injector and to induce spatial focusing of the ions along the Y direction when they return to the vicinity of the ion injector—only two opposing mirrors need be utilised. A further advantage accrues from an embodiment in which the opposing mirrors are curved towards each other with parabolic profiles as they elongate away from one end of the spectrometer adjacent an ion injector as this particular geometry further advantageously causes the ions to take the same time to return to their point of injection independent of their initial drift velocity.
The two elongated ion-optical mirrors may be similar to each other or they may differ. For example, one mirror may comprise a grid whilst the other may not; one mirror may comprise a curved portion whilst the other mirror may be straight. Preferably both mirrors are gridless and similar to each other. Most preferably the mirrors are gridless and symmetrical.
Preferably, an ion injector injects ions from one end of the mirrors into the space between the mirrors at an inclination angle to the X axis in the X-Y plane such that ions are reflected from one opposing mirror to the other a plurality of times whilst drifting along the drift direction away from the ion injector so as to follow a generally zigzag path within the mass spectrometer. The motion of ions along the drift direction is opposed by an electric field component resulting from the non-constant distance of the mirrors from each other along at least a portion of their lengths in the drift direction and the said electric field component causes the ions to reverse their direction and travel back towards the ion injector. The ions may undergo an integer or a non-integer number of complete oscillations between the mirrors before returning to the vicinity of the ion injector. Preferably, the inclination angle of the ion beam to the X axis decreases with each reflection in the mirrors as the ions move along the drift direction away from the injector. Preferably, this continues until the inclination angle is reversed in direction and the ions return back along the drift direction towards the injector.
Preferably embodiments of the present invention further comprise a detector located in a region adjacent the ion injector. Preferably the ion injector is arranged to have a detection surface which is parallel to the drift direction Y, i.e. the detection surface is parallel to the Y axis.
The multi-reflection mass spectrometer may form all or part of a multi-reflection time-of-flight mass spectrometer. In such embodiments of the invention, preferably the ion detector located in a region adjacent the ion injector is arranged to have a detection surface which is parallel to the drift direction Y, i.e. the detection surface is parallel to the Y axis. Preferably the ion detector is arranged so that ions that have traversed the mass spectrometer, moving forth and back along the drift direction as described above, impinge upon the ion detection surface and are detected. The ions may undergo an integer or a non-integer number of complete oscillations between the mirrors before impinging upon a detector. The ions preferably undergo only one oscillation in the drift direction in order that the ions do not follow the same path more than once so that there is no overlap of ions of different m/z, thus allowing full mass range analysis. However if a reduced mass range of ions is desired or is acceptable, more than one oscillation in the drift direction may be made between the time of injection and the time of detection of ions, further increasing the flight path length.
Additional detectors may be located within the multi-reflection mass spectrometer, with or without additional ion beam deflectors. Additional ion beam deflectors may be used to deflect ions onto one or more additional detectors, or alternatively additional detectors may comprise partially transmitting surfaces such as diaphragms or grids so as to detect a portion of an ion beam whilst allowing a remaining portion to pass on. Additional detectors may be used for beam monitoring in order to detect the spatial location of ions within the spectrometer, or to measure the quantity of ions passing through the spectrometer, for example. Hence more than one detector may be used to detect at least some of the ions during or after their passage through the mass spectrometer.
The multi-reflection mass spectrometer may form all or part of a multi-reflection electrostatic trap mass spectrometer, as will be further described. In such embodiments of the invention, the detector located in a region adjacent the ion injector preferably comprises one or more electrodes arranged to be close to the ion beam as it passes by, but located so as not to intercept it, the detection electrodes connected to a sensitive amplifier enabling the image current induced in the detection electrodes to be measured.
Advantageously, embodiments of the present invention may be constructed without the inclusion of any additional lenses or diaphragms in the region between the opposing ion optical mirrors. However additional lenses or diaphragms might be used with the present invention in order to affect the phase-space volume of ions within the mass spectrometer and embodiments are conceived comprising one or more lenses and diaphragms located in the space between the mirrors.
Preferably the multi-reflection mass spectrometer further comprises compensation electrodes, extending along at least a portion of the drift direction in or adjacent the space between the mirrors. Compensation electrodes allow further advantages to be provided, in particular in some embodiments that of reducing time-of-flight aberrations.
In some embodiments of the present invention, compensation electrodes are used with opposing ion optical mirrors elongated generally along the drift direction, each mirror opposing the other in an X direction, the X direction being orthogonal to Y, characterized in that the mirrors are not a constant distance from each other in the X direction along at least a portion of their lengths in the drift direction. In other embodiments of the invention, compensation electrodes are used with opposing ion optical mirrors elongated generally along the drift direction, each mirror opposing the other in an X direction, the X direction being orthogonal to Y, the mirrors being maintained a constant distance from each other in the X direction along their lengths in the drift direction. In both cases preferably the compensation electrodes create components of electric field which oppose ion motion along the +Y direction along at least a portion of the ion optical mirror lengths in the drift direction. These components of electric field preferably provide or contribute to a returning force upon the ions as they move along the drift direction.
The one or more compensation electrodes may be of any shape and size relative to the mirrors of the multi-reflection mass spectrometer. In preferred embodiments the one or more compensation electrodes comprise extended surfaces parallel to the X-Y plane facing the ion beam, the electrodes being displaced in +/−Z from the ion beam flight path, i.e. each one or more electrodes preferably having a surface substantially parallel to the X-Y plane, and where there are two such electrodes, preferably being located either side of a space extending between the opposing mirrors. In another preferred embodiment, the one or more compensation electrodes are elongated in the Y direction along a substantial portion of the drift length, each electrode being located either side of the space extending between the opposing mirrors. In this embodiment preferably the one or more compensation electrodes are elongated in the Y direction along a substantial portion, the substantial portion being at least one or more of: 1/10; ⅕; ¼; ⅓; ½; ¾ of the drift length. Preferably the one or more compensation electrodes comprise two compensation electrodes elongated in the Y direction along a substantial portion of the drift length, the substantial portion being at least one or more of: 1/10; ⅕; ¼; ⅓; ½; ¾ of the drift length, one electrode displaced in the +Z direction from the ion beam flight path, the other electrode displaced in the −Z direction from the ion beam flight path, the two electrodes thereby being located either side of a space extending between the opposing mirrors. However other geometries are anticipated. Preferably, the compensation electrodes are electrically biased in use such that the total time of flight of ions is substantially independent of the incidence angle of the ions. As the total drift length traveled by the ions is dependent upon the incidence angle of the ions, the total time of flight of ions is substantially independent of the drift length traveled.
Compensation electrodes may be biased with an electrical potential. Where a pair of compensation electrodes is used, each electrode of the pair may have the same electrical potential applied to it, or the two electrodes may have differing electrical potentials applied. Preferably where there are two electrodes, the electrodes are located symmetrically either side of a space extending between the opposing mirrors and the electrodes are both electrically biased with substantially equal potentials.
In some embodiments, one or more pairs of compensation electrodes may have each electrode in the pair biased with the same electrical potential and that electrical potential may be zero volts with respect to what is herein termed as an analyser reference potential. Typically the analyser reference potential will be ground potential, but it will be appreciated that the analyser may be arbitrarily raised in potential, i.e. the whole analyser may be floated up or down in potential with respect to ground. As used herein, zero potential or zero volts is used to denote a zero potential difference with respect to the analyser reference potential and the term non-zero potential is used to denote a non-zero potential difference with respect to the analyser reference potential. Typically the analyser reference potential is, for example, applied to shielding such as electrodes used to terminate mirrors, and as herein defined is the potential in the drift space between the opposing ion optical mirrors in the absence of all other electrodes besides those comprising the mirrors.
In preferred embodiments, two or more pairs of opposing compensation electrodes are provided. In such embodiments, some pairs of compensation electrodes in which each electrode is electrically biased with zero volts are further referred to as unbiased compensation electrodes, and other pairs of compensation electrodes having non-zero electric potentials applied are further referred to as biased compensation electrodes. Preferably, where each of the biased compensation electrodes has a surface having a polynomial profile in the X-Y plane, the unbiased compensation electrodes have surfaces complimentarily shaped with respect to the biased compensation electrodes, examples of which will be further described. Typically the unbiased compensation electrodes terminate the fields from biased compensation electrodes. In a preferred embodiment, surfaces of at least one pair of compensation electrodes have a parabolic profile in the X-Y plane, such that the said surfaces extend towards each mirror a greater distance in the regions near one or both the ends of the mirrors than in the central region between the ends. In another preferred embodiment, at least one pair of compensation electrodes have surfaces having a polynomial profile in the X-Y plane, more preferably a parabolic profile in the X-Y plane, such that the said surfaces extend towards each mirror a lesser distance in the regions near one or both the ends of the mirrors than in the central region between the ends. In such embodiments preferably the pair(s) of compensation electrodes extend along the drift direction Y from a region adjacent an ion injector at one end of the elongated mirrors, and the compensation electrodes are substantially the same length in the drift direction as the extended mirrors, and are located either side of a space between the mirrors. In alternative embodiments, the compensation electrode surfaces as just described may be made up of multiple discrete electrodes.
In other embodiments, compensation electrodes may be located partially or completely within the space extending between the opposing mirrors, the compensation electrodes comprising a set of separate tubes or compartments. Preferably the tubes or compartments are centred upon the X-Y plane and are located along the drift length so that ions pass through the tubes or compartments and do not impinge upon them. The tubes or compartments preferably have different lengths at different locations along the drift length, and/or have different electrical potentials applied as a function of their location along the drift length.
Preferably, in all embodiments of the present invention, the compensation electrodes do not comprise ion optical mirrors in which the ion beam encounters a potential barrier at least as large as the kinetic energy of the ions in the drift direction. However, as has already been stated and will be further described, they preferably create components of electric field which oppose ion motion along the +Y direction along at least a portion of the ion optical mirror lengths in the drift direction.
Preferably the one or more compensation electrodes are, in use, electrically biased so as to compensate for at least some of the time-of-flight aberrations generated by the opposing mirrors. Where there is more than one compensation electrode, the compensation electrodes may be biased with the same electrical potential, or they may be biased with different electrical potentials. Where there is more than one compensation electrode one or more of the compensation electrodes may be biased with a non-zero electrical potential whilst other compensation electrodes may be held at another electrical potential, which may be zero potential. In use, some compensation electrodes may serve the purpose of limiting the spatial extent of the electric field of other compensation electrodes. Preferably where there is a first pair of opposing compensation electrodes spaced either side of the beam flight path between the mirrors of the multi-reflection mass spectrometer, the first pair of compensation electrodes will be electrically biased with the same non-zero potential, and, the multi-reflection mass spectrometer further preferably comprises two additional pairs of compensation electrodes, which are located either side of the first pair of compensation electrodes in +/−X directions, the further pairs of compensation electrodes being held at zero potential, i.e. being unbiased compensation electrodes. In another preferred embodiment, three pairs of compensation electrodes are utilised, with a first pair of unbiased compensation electrodes held at zero potential and either side of these compensation electrodes in +/−X directions two further pairs of biased compensation electrodes held at a non-zero electrical potential. In some embodiments, one or more compensation electrodes may comprise a plate coated with an electrically resistive material which has different electrical potentials applied to it at different ends of the plate in the Y direction, thereby creating an electrode having a surface with a varying electrical potential across it as a function of the drift direction Y. Accordingly, electrically biased compensation electrodes may be held at no one single potential. Preferably the one or more compensation electrodes are, in use, electrically biased so as to compensate for a time-of-flight shift in the drift direction generated by the opposing mirrors and so as to make a total time-of-flight shift of the system substantially independent of an initial ion beam trajectory inclination angle in the X-Y plane, as will be further described. The electrical potentials applied to compensation electrodes may be held constant or may be varied in time. Preferably the potentials applied to the compensation electrodes are held constant in time whilst ions propagate through the multi-reflection mass spectrometer. The electrical bias applied to the compensation electrodes may be such as to cause ions passing in the vicinity of a compensation electrode so biased to decelerate, or to accelerate, the shapes of the compensation electrodes differing accordingly, examples of which will be further described.
As herein described, the term “width” as applied to compensation electrodes refers to the physical dimension of the biased compensation electrode in the +/−X direction.
Preferably, the compensation electrodes are so configured and biased in use to create one or more regions in which an electric field component in the Y direction is created which opposes the motion of the ions along the +Y drift direction. The compensation electrodes thereby cause the ions to lose velocity in the drift direction as they proceed along the drift length in the +Y direction and the configuration of the compensation electrodes and biasing of the compensation electrodes is arranged to cause the ions to turn around in the drift direction before reaching the end of the mirrors and return back towards the ion injection region. Advantageously this is achieved without sectioning the opposing mirrors and without introducing a third mirror. Preferably the ions are brought to a spatial focus in the region of the ion injector where a suitable detection surface is arranged, as described for other embodiments of the invention. Preferably the electric field in the Y direction creates a force which opposes the motion of ions linearly as a function of distance in the drift direction (a quadratic opposing electrical potential) as will be further described.
Preferably, methods of mass spectrometry using the present invention further comprise injecting ions into a multi-reflection mass spectrometer comprising compensation electrodes, extending along at least a portion of the drift direction in or adjacent the space between the mirrors. Preferably the ions are injected from an ion injector located at one end of the opposing mirrors in the drift direction and in some embodiments ions are detected by impinging upon a detector located in a region in the vicinity of the ion injector, e.g. adjacent thereto. In other embodiments ions are detected by image current detection means, as described above. The mass spectrometer to be used in the method of the present invention may further comprise components with details as described above.
The present invention further provides an ion optical arrangement comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, characterized in that the mirrors are not a constant distance from each other in the X direction along at least a portion of their lengths in the drift direction. In use, ions are reflected between the ion optical mirrors whilst proceeding a distance along the drift direction between reflections, the ions reflecting a plurality of times, and the said distance varies as a function of the ions' position along at least part of the drift direction. The ion-optical arrangement may further comprise one or more compensation electrodes each electrode being located in or adjacent the space extending between the opposing mirrors, the compensation electrodes being arranged and electrically biased in use so as to produce, in the X-Y plane, an electrical potential offset which: (i) varies as a function of the distance along the drift length along at least a portion of the drift length, and/or; (ii) has a different extent in the X direction as a function of the distance along the drift length along at least a portion of the drift length.
In some preferred embodiments which will be further described, the ion beam velocity is changed in such a way that all time-of-flight aberrations caused by non-parallel opposing ion optical mirrors are corrected. In such embodiments it is found that the change of the oscillation period resulting from a varying distance between the mirrors along the drift length is completely compensated by the change of the oscillation period resulting from the electrically biased compensation electrodes, in which case ions undergo a substantially equal oscillation time on each oscillation between the opposing ion-optical mirrors at all locations along the drift length even though the distance between the mirrors changes along the drift length. In other preferred embodiments of the invention the electrically biased compensation electrodes correct substantially the oscillation period so that the time-of-flight aberrations caused by non-parallel opposing ion optical mirrors are substantially compensated and only after a certain number of oscillations when the ions reach the plane of detection. It will be appreciated that for these embodiments, in the absence of the electrically biased compensation electrodes, the ion oscillation period between the opposing ion-optical mirrors would not be substantially constant, but would reduce as the ions travel along portions of the drift length in which the opposing mirrors are closer together.
Accordingly, the present invention further provides a method of mass spectrometry comprising the steps of injecting ions into an injection region of a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, so that the ions oscillate between the opposing mirrors whilst proceeding along a drift length in the Y direction; the spectrometer further comprising one or more compensation electrodes each electrode being located in or adjacent the space extending between the opposing mirrors, the compensation electrodes being, in use, electrically biased such that the period of ion oscillation between the mirrors is substantially constant along the whole of the drift length; and detecting at least some of the ions during or after their passage through the mass spectrometer.
The present invention further provides a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, and further comprising one or more compensation electrodes each electrode being located in or adjacent the space extending between the opposing mirrors, the spectrometer further comprising an ion injector located at one end of the ion-optical mirrors in the drift direction arranged so that in use it injects ions such that they oscillate between the opposing mirrors whilst proceeding along a drift length in the Y direction; the compensation electrodes being, in use, electrically biased such that the period of ion oscillation between the mirrors is substantially constant along the whole of the drift length.
The present invention still further provides a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, and an ion injector located at one end of the ion-optical mirrors in the drift direction arranged so that in use it injects ions such that they oscillate between the opposing mirrors whilst proceeding along a drift length in the Y direction; characterised in that the amplitude of ion oscillation between the mirrors is not substantially constant along the whole of the drift length. Preferably the amplitude decreases along at least a portion of the drift length as ions proceed away from the ion injector. Preferably the ions are turned around after passing along the drift length and proceed back along the drift length towards the ion injector. The present invention still further provides a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, and an ion injector located at one end of the ion-optical mirrors in the drift direction arranged so that in use it injects ions such that they oscillate between the opposing mirrors whilst proceeding along a drift length in the Y direction; characterised in that the distance between equipotential surfaces at which the ions turn in the +/−X direction is not substantially constant along the whole of the drift length.
The present invention further provides a method of mass spectrometry comprising the steps of injecting ions into a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, reflecting the ions from one mirror to the other generally orthogonally to the drift direction a plurality of times by turning the ions within each mirror whilst the ions proceed along the drift direction Y, characterized in that the distance between consecutive points in the X direction at which the ions turn monotonously changes with Y during at least a part of the motion of the ions along the drift direction; and detecting at least some of the ions during or after their passage through the mass spectrometer.
As already described, preferably one or more compensation electrodes are so configured and biased in use to create one or more regions in which an electric field component in the Y direction is created which opposes the motion of the ions along the +Y drift direction. Compensation electrodes as described herein may be used to provide at least some of the advantages of the present invention when used with two opposing ion-optical mirrors elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, the mirrors being a constant distance from each other, i.e. having an equal gap between them along the whole of their lengths in the drift direction, the average reflection surfaces of the opposing mirrors being a constant distance from each other along the whole of the drift length. In such embodiments, the opposing mirrors may be straight and arranged parallel to each other, for example, in which case the mirrors are a constant distance from each other in the X direction. In other embodiments the mirrors may be curved but be arranged to have an equal gap between them, i.e. they may be curved so as to form opposed sector shapes, with a constant gap between the sectors. In other embodiments the mirrors may form more complex shapes, but the mirrors have complementing shapes and the gap between them remains constant. The compensation electrodes preferably extend along at least a portion of the drift direction, each electrode being located in or adjacent the space extending between the opposing mirrors, the compensation electrodes being shaped and electrically biased in use so as to produce, in at least a portion of the space extending between the mirrors, an electrical potential offset which: (i) varies as a function of the distance along the drift length, and/or; (ii) has a different extent in the X direction as a function of the distance along the drift length. In these embodiments the compensation electrodes being so configured (i.e. shaped and arranged in space) and biased in use create one or more regions in which an electric field component in the Y direction is created which opposes the motion of the ions along the +Y drift direction. As the ions are repeatedly reflected from one ion optical mirror to the other and at the same time proceed along the drift length, the ions turn within each mirror. The distance between subsequent points at which the ions turn in the Y-direction changes monotonously with Y during at least a part of the motion of the ions along the drift direction, and the period of ion oscillation between the mirrors is not substantially constant along the whole of the drift length. The electrically biased compensation electrodes cause the ion velocity in the X direction (at least) to be altered along at least a portion of the drift length, and the period of the ion oscillation between the mirrors is thereby changed as a function of the at least a portion of the drift length. In such embodiments both mirrors are elongated along the drift direction and are arranged an equal distance apart in the X direction. In some embodiments both mirrors are elongated non-linearly along the drift direction and in other embodiments both mirrors are elongated linearly along the drift direction. Preferably for ease of manufacture both mirrors are elongated linearly along the drift direction, i.e. both mirrors are straight. In embodiments of the invention the period of ion oscillation decreases along at least a portion of the drift length as ions proceed away from the ion injector. Preferably the ions are turned around after passing along the drift length and proceed back along the drift length towards the ion injector. In embodiments of the present invention, compensation electrodes are used to alter the ion beam velocity and, therefore, the ion oscillation periods, as the ion beam passes near to a compensation electrode, or more preferably between a pair of compensation electrodes. The compensation electrodes thereby cause the ions to lose velocity in the drift direction and the configuration of the compensation electrodes and biasing of the compensation electrodes is arranged to preferably cause the ions to turn around in the drift direction before reaching the end of the mirrors and return back towards the ion injection region. Advantageously this is achieved without sectioning the opposing mirrors and without introducing a third mirror. Preferably the ions are brought to a spatial focus in the region of the ion injector where a suitable detection surface is arranged, as previously described for other embodiments of the invention. Preferably the electric field in the Y direction creates a force which opposes the motion of ions linearly as a function of distance in the drift direction (a quadratic opposing electrical potential) as will be further described.
Accordingly, embodiments of the present invention further provide a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y; the mass spectrometer further comprising one or more compensation electrodes each electrode being located in or adjacent the space extending between the opposing mirrors; the spectrometer further comprising an ion injector located at one end of the ion-optical mirrors in the drift direction, arranged so that in use it injects ions such that they oscillate between the ion-optical mirrors, reflecting from one mirror to the other generally orthogonally to the drift direction a plurality of times, turning the ions within each mirror whilst the ions proceed along the drift direction Y; characterized in that the compensation electrodes are, in use, electrically biased such that the distance between subsequent points at which the ions turn in the Y-direction changes monotonously with Y during at least a part of the motion of the ions along the drift direction. In addition, embodiments of the present invention also provide a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, further comprising one or more compensation electrodes each electrode being located in or adjacent the space extending between the opposing mirrors, the compensation electrodes being electrically biased in use; the mass spectrometer further comprising an ion injector located at one end of the ion-optical mirrors in the drift direction, arranged so that in use it injects ions such that they oscillate between the opposing mirrors whilst proceeding along a drift length in the Y direction; characterised in that the period of ion oscillation between the mirrors is not substantially constant along the whole of the drift length. Embodiments of the present invention also provide a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y; the mass spectrometer further comprising one or more compensation electrodes each electrode being located in or adjacent the space extending between the opposing mirrors; the compensation electrodes being configured and electrically biased in use so as to produce, in at least a portion of the space extending between the mirrors, an electrical potential offset which: (i) varies as a function of the distance along the drift length, and/or; (ii) has a different extent in the X direction as a function of the distance along the drift length.
The invention further provides a method of mass spectrometry comprising the steps of injecting ions into a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, the mass spectrometer further comprising one or more electrically biased compensation electrodes, each electrode being located in or adjacent the space extending between the opposing mirrors; reflecting the ions from one mirror to the other generally orthogonally to the drift direction a plurality of times by turning the ions within each mirror whilst the ions proceed along the drift direction Y, characterized in that the compensation electrodes produce in at least a portion of the space extending between the mirrors, an electrical potential offset which: (i) varies as a function of the distance along the drift length, and/or; (ii) has a different extent in the X direction as a function of the distance along the drift length; and detecting at least some of the ions during or after their passage through the mass spectrometer. The invention further provides a method of mass spectrometry comprising the steps of injecting ions into a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction, the X direction being orthogonal to Y, the mass spectrometer further comprising one or more electrically biased compensation electrodes, each electrode being located in or adjacent the space extending between the opposing mirrors; reflecting the ions from one mirror to the other generally orthogonally to the drift direction a plurality of times by turning the ions within each mirror whilst the ions proceed along the drift direction Y, characterized in that the distance between subsequent points in the Y-direction at which the ions turn monotonously changes with Y during at least a part of the motion of the ions along the drift direction and; detecting at least some of the ions during or after their passage through the mass spectrometer. The invention still further provides a method of mass spectrometry comprising the steps of: injecting ions into a multi-reflection mass spectrometer comprising two ion-optical mirrors, each mirror elongated generally along a drift direction (Y), each mirror opposing the other in an X direction and having a space therebetween, the X direction being orthogonal to Y, further comprising one or more compensation electrodes each electrode being located in or adjacent the space extending between the opposing mirrors; applying electrical biases to the mirrors and the compensation electrodes; the ions being injected from an ion injector located at one end of the ion-optical mirrors in the drift direction such that they oscillate between the opposing mirrors whilst proceeding along a drift length in the Y direction, characterised in that the period of ion oscillation between the mirrors is not substantially constant along the whole of the drift length and; detecting at least some of the ions during or after their passage through the mass spectrometer.
As described above, in some preferred embodiments the ion-optical mirrors are arranged so that the average reflection surfaces of the opposing mirrors are not a constant distance from each other in the X direction along at least a portion of the drift length. Alternatively in other embodiments the ion optical mirrors are arranged so that the average reflection surfaces of the opposing mirrors are maintained a constant distance from each other in the X direction along the whole drift length and the mass spectrometer further comprises electrically biased compensation electrodes as previously described. Most preferably the ion-optical mirrors are arranged so that the average reflection surfaces of the opposing mirrors are not a constant distance from each other in the X direction along at least a portion of the drift length and the mass spectrometer further comprises electrically biased compensation electrodes as previously described, in which case it is more preferable that the compensation electrodes are electrically biased such that the period of ion oscillation between the mirrors is substantially constant along the whole of the drift length.
In some preferred embodiments, the space between the opposing ion optical mirrors is open ended in the X-Z plane at each end of the drift length, whether the average reflection surfaces of the opposing mirrors are not a constant distance from each other in the X direction along at least a portion of the drift length or where the ion optical mirrors are arranged so that the average reflection surfaces of the opposing mirrors are maintained a constant distance from each other in the X direction along the whole drift length. By open ended in the X-Z plane it is meant that the mirrors are not bounded by electrodes in the X-Z plane which fully or substantially span the gap between the mirrors.
Embodiments of the multi-reflection mass spectrometer of the present invention may form all or part of a multi-reflection electrostatic trap mass spectrometer. A preferred electrostatic trap mass spectrometer comprises two multi-reflection mass spectrometers arranged end to end symmetrically about an X axis such that their respective drift directions are collinear, the multi-reflection mass spectrometers thereby defining a volume within which, in use, ions follow a closed path with isochronous properties in both the drift directions and in an ion flight direction.
The multi-reflection mass spectrometer of the present invention may form all or part of a multi-reflection time-of-flight mass spectrometer.
A composite mass spectrometer may be formed comprising two or more multi-reflection mass spectrometers aligned so that the X-Y planes of each mass spectrometer are parallel and optionally displaced from one another in a perpendicular direction Z, the composite mass spectrometer further comprising ion-optical means to direct ions from one multi-reflection mass spectrometer to another. In one such embodiment of a composite mass spectrometer a set of multi-reflection mass spectrometers are stacked one upon another in the Z direction and ions are passed from a first multi-reflection mass spectrometer in the stack to further multi-reflection mass spectrometers in the stack by means of deflection means, such as electrostatic electrode deflectors, thereby providing an extended flight path composite mass spectrometer in which ions do not follow the same path more than once, allowing full mass range TOF analysis as there is no overlap of ions. In another such embodiment of a composite mass spectrometer a set of multi-reflection mass spectrometers are each arranged to lie in the same X-Y plane and ions are passed from a first multi-reflection mass spectrometer to further multi-reflection mass spectrometers by means of deflection means, such as electrostatic electrode deflectors, thereby providing an extended flight path composite mass spectrometer in which ions do not follow the same path more than once, allowing full mass range TOF analysis as there is no overlap of ions. Other arrangements of multi-reflection mass spectrometers are envisaged in which some of the spectrometers lie in the same X-Y plane and others are displaced in the perpendicular Z direction, with ion-optical means arranged to pass ions from spectrometer to another thereby providing an extended flight path composite mass spectrometer in which ions do not follow the same path more than once. Preferably, where some spectrometers are stacked in Z direction, the said spectrometers have alternating orientations of the drift directions to avoid the requirement for deflection means in the drift direction.
Alternatively, embodiments of the present invention may be used with a further beam deflection means arranged to turn ions around and pass them back through the multi-reflection mass spectrometer or composite mass spectrometer one or more times, thereby multiplying the flight path length, though at the expense of mass range.
Analysis systems for MS/MS may be provided using the present invention comprising a multi-reflection mass spectrometer and, an ion injector comprising an ion trapping device upstream of the mass spectrometer, and a pulsed ion gate, a high energy collision cell and a time-of-flight analyser downstream of the mass spectrometer. Moreover, the same analyser could be used for both stages of analysis or multiple such stages of analysis thereby providing the capability of MSn, by configuring the collision cell so that ions emerging from the collision cell are directed back into the ion trapping device.
The present invention provides a multi-reflection mass spectrometer and method of mass spectrometry comprising opposing mirrors elongated along a drift direction and means to provide a returning force opposing ion motion along the drift direction. In the present invention the returning force is smoothly distributed along a portion of the drift direction, most preferably along substantially the whole of the drift direction, reducing or eliminating uncontrolled ion scattering especially near the turning point in the drift direction where the ion beam width is at its maximum. This smooth returning force is in some embodiments provided through the use of continuous, non-sectioned electrode structures present in the mirrors, the mirrors being inclined or curved to one another along at least a portion of the drift length, preferably most of the drift length. In other embodiments the returning force is provided by electric field components produced by electrically biased compensation electrodes. In particularly preferred embodiments the returning force is provided both by opposing ion optical mirrors being inclined or curved to one another at one end and by the use of biased compensation electrodes. Notably the returning force is not provided by a potential barrier at least as large as the ion beam kinetic energy in the drift direction.
In systems of two opposing elongated mirrors alone, the implementation of a returning force, by, for example one or more electrodes in the X-Z plane at the end of the drift length, or by inclining the mirrors, will necessarily introduce time-of-flight aberrations dependent upon the initial ion beam injection angle, because the electric field in the vicinity of the returning force means cannot be represented simply by the sum of two terms, one being a term for the field in the drift direction (Ey) and one being a term for the field transverse to the drift direction (Ex). Substantial minimization of such aberrations is provided in the present invention by the use of compensation electrodes, accruing a further advantage to such embodiments.
The time-of-flight aberrations of some embodiments of the present invention can be considered as follows, in relation to a pair of opposing ion optical mirrors elongated in their lengths along a drift direction Y and which are progressively inclined closer together in the X direction along at least a portion of their lengths. An initial pulse of ions entering the mirror system will comprise ions having a range of injection angles in the X-Y plane. A set of ions having a larger Y velocity will proceed down the drift length a little further at each oscillation between the mirrors than a set of ions with a lower Y velocity. The two sets of ions will have a different oscillation time between the mirrors because the mirrors are inclined to one another by a differing amount as a function of the drift length. In preferred embodiments the mirrors are closer together at a distal end from the ion injection means. The ions with higher Y velocity will encounter a pair of mirrors with slightly smaller gap between them than will the ions having lower Y velocity, on each oscillation within the portion of the mirrors which has mirror inclination. This may be compensated for by the use of one or more compensation electrodes. To illustrate this, a pair of compensation electrodes will be considered (as a non-limiting example), extending along the drift direction adjacent the space between the mirrors, comprising extended surfaces in the X-Y plane facing the ion beam, each electrode located either side of a space extending between the opposing mirrors. Suitable electrical biasing of both electrodes by, for example, a positive potential, will provide a region of space between the mirrors in which positive ions will proceed at lower velocity. If the biased compensation electrodes are arranged so that the extent of the region of space between them in the X direction varies as a function of Y then the difference in the oscillation time between the mirrors for ions of differing Y velocity may be compensated. Various means for providing that the region of space in the X direction varies as a function of Y may be contemplated, including: (a) using biased compensation electrodes shaped so that they extend in the +/−X directions a differing amount as a function of Y (i.e. they present a varying width in X as they extend in Y), or (b) using compensation electrodes that are spaced apart from one another a differing amount in Z as a function of Y. Alternatively, the amount of velocity reduction may be varied as a function of Y, by using, for example, using constant width compensation electrodes, each biased with a voltage which varies along their length as a function of Y and again the difference in the oscillation time between the mirrors for ions of differing Y velocity may thereby be compensated. Of course a combination of these means may also be used, and other methods may also be found, including for example, the use of additional electrodes with different electrical biasing, spaced along the drift length. The compensation electrodes, examples of which will be further described in detail, compensate at least partially for time-of-flight aberrations relating to the beam injection angular spread in the X-Y plane. Preferably the compensation electrodes compensate for time-of-flight aberrations relating to the beam injection angular spread in the X-Y plane to first order, and more preferably to second or higher order.
Advantageously, aspects of the present invention allow the number of ion oscillations within the mirrors structure and thereby the total flight path length to be altered by changing the ion injection angle. In some preferred embodiments biasing of the compensation electrodes is changeable in order to preserve the time-of-flight aberration correction for different number of oscillations as will be further described.
In embodiments of the present invention, the ion beam slowly diverges in the drift direction as the beam progresses towards the distal end of the mirrors from the ion injector, is reflected solely by means of a component of the electric field acting in the −Y direction which is produced by the opposing mirrors themselves and/or, where present, by the compensating electrodes, and the beam slowly converges again upon reaching the vicinity of the ion injector. The ion beam is thereby spread out in space to some extent during most of this flight path and space charge interactions are thereby advantageously reduced.
Time-of-flight focusing is also provided by the non-parallel mirror arrangement of some embodiments of the invention together with suitably shaped compensation electrodes, as described earlier; time-of-flight focusing with respect to the spread of injection angles is provided by the non-parallel mirror arrangement of the invention and correspondingly shaped compensating electrodes. Time of flight focusing with respect to energy spread in the X direction is also provided by the special construction of the ion mirrors, generally known from the prior art and more fully described below. As a result of time-of-flight focussing in both X and Y directions, the ions arrive at substantially same coordinate in the Y direction in the vicinity of the ion injector after a designated number of oscillations between the mirrors in X direction. Spatial focussing on the detector is thereby achieved without the use of additional focusing elements and the mass spectrometer construction is greatly simplified. The mirror structures may be continuous, i.e. not sectioned, and this eliminates ion beam scattering associated with the step-wise change in the electric field in the gaps between such sections, especially near the turning point in the drift direction where the ion beam width is at its maximum. It also enables a much simpler mechanical and electrical construction of the mirrors, providing a less complex analyser. Only two mirrors are required. Furthermore, in some embodiments of the invention the time-of-flight aberrations created due to the non-parallel opposing mirror structure may be largely eliminated by the use of compensation electrodes, enabling high mass resolving power to be achieved at a suitably placed detector. Many problems associated with prior art multi-reflecting mass analysers are thereby solved by the present invention.
In a further aspect of the present invention there is provided a method of injecting ions into a time-of-flight spectrometer or electrostatic trap at a first angle +θ to an axis, comprising the steps of: ejecting a substantially parallel beam of ions radially from a storage multipole at a second angle with respect to the said axis and; deflecting the ions by a third angle by passing the ions through an electrostatic deflector, so that the ions then travel into the time-of-flight spectrometer or electrostatic trap, the second and third inclination angles being approximately equal. The present invention further provides an ion injector apparatus for injecting ions into a time-of-flight spectrometer or electrostatic trap at a first angle +θ to an axis, comprising: a storage multipole arranged to eject, in use, ions radially at a second angle with respect to the said axis and; an electrostatic deflector to receive the said ions and deflect, in use, the ions through a third angle so that the ions pass into the time-of-flight spectrometer or electrostatic trap at the first angle +θ to an axis, the second and third inclination angles being approximately equal. Hence the second and third angles are approximately +θ/2. Preferably the time-of-flight spectrometer is a mass spectrometer. The deflector is implemented by any knows means, for example, the deflector may comprise a pair of opposing electrodes. Preferably the pair of opposing electrodes comprise electrodes held a constant distance from each other. The pair of electrodes may be straight, or they may be curved; preferably the pair of electrodes comprises straight electrodes. Preferably the pair of electrodes is biased with a bipolar set of potentials.
The ions are ejected from the storage multipole in a substantially parallel beam and accordingly, a first set of ions ejected from one end of the storage multipole emerge closer to the spectrometer or trap than a second set of ions ejected simultaneously from the other end of the storage multipole, due to the storage multipole inclination angle +θ/2, and accordingly the first set of ions would reach the time-of-flight mass spectrometer or trap before the second set of ions if no deflection means are implemented in between the storage multipole and the spectrometer or trap. The electrostatic deflector compensates the said time-of-flight difference and, simultaneously, doubles the ion beam inclination. To illustrate the time-of-flight compensation, we firstly suppose the ion beam to comprise positive ions, and the first set of ions pass through a first region of the deflector and the second set of ions pass through the second region of the deflector without substantially overlapping inside the deflector. To deflect the positive ions, the electric potential in the first region is more positive, on average, than the electric potential in the second region, which is achieved, for example, by applying a more positive voltage to a first deflecting electrode which is closer to the first region and by applying a less positive voltage to a second deflecting electrode which is nearer to the second region. The average electric potential difference necessarily has two effects: (i) it produces the desired deflecting electric field and (ii) it makes the first set of ions proceed through the deflector more slowly than the second set of ions due to the full energy conservation law—a time-of-flight effect. This time-of-flight effect makes both sets of ions emerge from the deflector to arrive at the time-of-flight spectrometer or electrostatic trap at the same time. The same principles apply were the beam comprising negative ions as the electrostatic deflector potentials would in that case be reversed.
Various embodiments of the present invention will now be described by way of the following examples and the accompanying figures.
One object of the present invention is to provide an elongated opposing ion-mirror structure in which a smooth returning force is produced.
The embodiment of
After a pair of reflections in mirrors 31 and 32, the inclination angle changes by the value Δθ=2×Ω(Y), where Ω=L′(Y) is convergence angle of the mirrors with the effective distance L(Y) between them. This angle change is equivalent to the inclination angle change on the 2×L(0) flight distance in the effective returning potential Φm(Y)=2V[L(0)−L(Y)]/L(0). Parabolic elongation L(Y)=L(0)−AY2, where A is a positive coefficient, generates a quadratic distribution of the returning potential in which the ions advantageously take the same time to return to the point of their injection Y=0 independent of their initial drift velocity in the Y direction. The mirror convergence angle Ω(Y) is advantageously small and doesn't affect the isochronous properties of mirrors 31, 32 in the X direction as will be described further in relation to
As known from the prior art, mirrors of this design can produce highly isochronous oscillation time periods for ions with energy spreads Δε/ε0>10%.
In use, the electrically biased compensation electrodes 65 generate potential distribution u(X,Y) in the plane of their symmetry Z=0, which is shown with schematic potential curve 69 in
The time-of-flight aberration of the embodiment in
The embodiment in
whilst the time-of-flight offset of the moment when an ion with given normalized turning point coordinate y0 impinges the detector's plane X=0 after a designated number of oscillations between the mirrors is proportional to integral
The deviation of function σ(y0) from σ(1) thus determines the time-of-flight aberration with respect to the injection angle.
Values of the coefficients m and c are to be found from the following conditions: (1) the integral σ is substantially constant (not necessarily zero) in the vicinity of y0=1, which corresponds to slow time-of-flight dependence on the injection angle in the interval θ±δθ/2, and (2) the integral τ has vanishing derivative τ′(1) to ensure at least first-order spatial focusing of the ions on the detector. The embodiment represented schematically in
The value of the mirror convergence angle is expressed through the coefficient m1=π/4 with formula Ω=m1L(0) sin2 θ/2Y0*. With the effective distance between the mirrors L(0) being comparable with the drift distance Y0* and the injection angle θ=50 mrad, the mirror convergence angle can be estimated as Ω≈1 mrad<<θ. Therefore,
In a similar manner, a multi-reflection mass spectrometer similar to that shown in
The embodiments in
Ideal spatial focusing, however, can be compromised in order to achieve better compensation of the time-of-flight aberration, that is make the integral σ(y0) as constant as possible in the vicinity of y0=1 even in the case of linearly elongated mirrors. An embodiment in
The drift length Ym* and injection angle θ should be chosen to define a designated number of full oscillations K=πτ(1)Ym*/(2L(0)tan θ) (each full oscillation comprises two reflections in the opposing mirrors) before the ions drift back to the point of their origin Y=0. The coefficient τ(1)=1 for the embodiments depicted in
Alternatively, an orthogonal ion accelerator can be used to inject the ion beam into the mass spectrometer as described in the U.S. Pat. No. 5,117,107 (Guilhaus and Dawson, 1992).
Ion bunch 112 undergoes an extra reflection in mirror 72 (i.e. undergoes a non-integer number of full oscillations between mirrors 71, 72) which advantageously allows more space for the storage multipole 111. A system of lenses (not shown) can be used to conjugate emittance of the storage multipole and acceptance of the mass spectrometer. A diaphragm 115 preferably shapes the ion beam before injection to the mass spectrometer and prior to detection. Due to low time-of-flight aberrations with respect to initial ion spread in drift direction, ion extraction from a long length of the storage multipole 111 is possible, which advantageously reduces space-charge effects.
The long axis of the storage multipole 111 lies in the plane of mass spectrometer but may be non-parallel to the drift axis Y and preferably constitutes angle θ/2 with this axis. After ejection from storage multipole 111 and upon acceleration, a substantially parallel beam of ions enter deflector 114 which turns trajectories 114 by a further angle θ/2 to constitute the designated injection angle θ (preferably 10-50 mrad). Deflector 114 may be implemented by any known means, e.g. as a pair of parallel electrodes 114-1 and 114-2, as shown in
As the ion beam approaches the distal end of mirrors 71, 72, the beam's angle of inclination in the X-Y plane gets progressively smaller until its sign is changed in the turning point (not shown) and the ion beam starts its return path towards detector 117. The ion beam width in the Y dimension reaches its maximum near the turning point and the trajectories of ions having undergone different numbers of oscillations overlap thus helping to average out space charge effects. The ions 116 come back to the detector 117 after designated integer number of full oscillations between mirrors 71 and 72. Diaphragm 115 may be used to limit the size of the beam in Y, if necessary. The sensitive surface of the detector 117 is preferably elongated in the drift direction parallel to the drift axis Y. Microchannel or microball plates as well as secondary electron multipliers could be used for detection. In addition, in a known manner post-acceleration (preferably by 5-15 kV) could be implemented prior to detection for better detection efficiency for high mass ions.
Compensation electrodes 95, 96 comprise two parallel electrodes displaced from the X-Y plane in the +/−Z directions (above and below the plane of ion motion). Compensation electrodes 95, 96 are provided with a voltage offset U (preferably of order of magnitude V sin2 θ) and have their shapes defined by the fourth order polynomial with the coefficients c0 . . . c4 as described in relation to embodiments in
The embodiment in
The optimal injection angle is θ=atan(πτ(1)Y0*/2KL(0))≈2.64 degrees, where L(0)≈0.64 m is the effective distance between the opposing mirrors in the vicinity of the ion injector. One half of this angle results from the inclination of the storage multipole 111, and the second half results from the deflection by deflector 112. The effective flight length is about (2K+1)L(0)≈32.6 m (including one extra reflection as shown in
For the parameters as above, the optimal mirror inclination angle is Ω=m1[L(0)/2Y0*] tan2 θ=0.0787 degrees, where m1=1.211 in agreement with column 4 of Table 1. Such an inclination angle corresponds to a mirror convergence by the amount of ΔL=L(Y0*)−L(0)=ΩY0*≈0.88 mm at the distal end of the drift region, and, in the absence of the compensation electrodes, the relative time-of-flight difference between two trajectories with the injection angles separated by δθ/θ≈20% could be estimated as (δθ/θ)×ΔL/L(0)≈3×10−4 with corresponding resolving power limited to the value 0.5/3×10−4≈1600.
The total width of the biased compensation electrodes 95 and 96 was chosen in agreement with present invention as a fourth-order polynomial S(y)=W[c1y+c2y2+c3y3+c4y4], where W=0.18 m, y=Y/Y0*, and coefficients c are as in column 4 of Table 1. The optimal voltage offset on the biased compensation electrodes 95 and 96 is U=−L0V tan2 θ/W=−37.8 V. In the presence of the biased compensation electrodes, the period of oscillation is not constant along the drift length but varies between approximately 18.495 us and 18.465 μs. The properly chosen profile of the compensation electrodes makes, however, the first-order time of flight aberration ∂Tk/∂θ to vanish after all K=25 oscillations are completed as shown in
The complete set of third order aberrations with respect to three initial coordinates and three initial velocity components was calculated to estimate the resolving power of the mass spectrometer. The time-of-flight spread δT of the ions with same mass and charge upon impinging the detector 117 is due to three major factors, simulated values of which are presented separately in
Both storage multipole 111 and detector 117 could be separated from the plane of symmetry of the mirrors (Z=0) and ions be directed into and out of this plane using known deflection means.
Embodiments of the invention such as those depicted schematically in
A bipolar voltage is initially applied to the pair of electrodes comprising deflector 124, is switched off after the highest-mass ions are deflected into the plane of symmetry and before the lightest-mass ions make a designated number of oscillations between mirrors 71-1 and 72-1 and return to the deflector 124. The ion beam proceeds to the mass spectrometer 130-2 and comes back to mass spectrometer 130-1 after a designated (preferably odd) number of oscillations between mirrors 71-2 and 72-2. The ion trajectories are thus spatially closed, and the ions are allowed to oscillate between the mass spectrometers 130-1, 130-2 repeatedly whilst no bipolar voltage is applied to deflector 124. A unipolar voltage offset could be also applied to electrodes 124 during ion motion in order to focus ion beam and sustain its stability.
Four pairs of stripe-shaped electrodes 131, 132 are used for readout of the induced-current signal on every pass of the ions between the mirrors. The electrodes in each pair are symmetrically separated in the Z-direction and can be located in the planes of compensation electrodes 97 or closer to the ion beam. Electrode pairs 131 are connected to the direct input of a differential amplifier (not shown) and electrode pairs 132 are connected to the inverse input of the differential amplifier, thus providing differential induced-current signal, which advantageously reduces the noise. To obtain the mass spectrum, the induced-current signal is processed in known ways using the Fourier transform algorithms or specialized comb-sampling algorithm, as described by J. B. Greenwood at al. in Rev. Sci. Instr. 82, 043103 (2011).
After a lapse of time, a bipolar voltage may be applied to the electrodes 124 to deflect the ions so that they are diverted from the electrostatic trap and impinge upon a detector 117 which may be a microchannel or microball plate, or a secondary electron multiplier, for example. Either one method of detection or both methods of detection (the induced-current signal from electrodes 131, 132 and the ion signal produced from ions impinging upon detector 117) could advantageously be employed on the same batch of ions.
Multi-reflection mass spectrometers of the present invention may be advantageously arranged to form a composite mass spectrometer.
Ions 141 are injected from the RF storage multipole 111 and the time-of-flight aberrations are corrected with deflector 114 as described in relation to the embodiment of
The number of full oscillations between mirrors 71 and 72 in each mass spectrometer is preferably odd, so that coordinate Z and velocity component Ż of each ion change their signs to opposite between two consequent transitions from one mass spectrometer to another by a pair of deflectors 143 and 142. Therefore the time-of-flight aberrations introduced by one transition are substantially compensated in the course of the next transition.
It will be appreciated that different numbers of multi-reflection mass spectrometers may be stacked one upon the other in this manner. Alternative arrangements may also be conceived in which some or all the multi-reflection mass spectrometers of the invention are located in the same X-Y plane, with ion-optical means to direct the ion beam from one spectrometer to another. All such composite mass spectrometers have the advantage of extended flight path lengths with only modest increases in volume.
The option of adjustable flight length advantageously allows higher repetition rate of mass analysis, though at the expense of mass resolving power. In the mass spectrometer of this invention, however, one cannot change the number of oscillations K by simple adjustment of the compensation electrodes bias voltage and/or the injection angle without violating the previously set conditions for aberration compensation. If some loss in aberration compensation is acceptable however, the oscillation number may be changed over a limited range by said means. Based on dependencies between the principal geometrical parameters tan θ=πτ(1)Y0*/2KL(0) and Ω=m1[L(0)/2Y0*] tan2 θ which are necessary for substantial aberration compensation, the variation of the number of oscillations K under preserved effective mirror separation L(0) and tilt Ω necessarily entails a change of the injection angle θ and the mean drift length Y0* in the following proportions: tan θ1/tan θ0=K1/K0 and Y1*/Y0*=(K1/K0)2. A change of the injection angle in this specified proportion can be realized electrically by means of deflector 161, implemented by various known means and schematically represented by two parallel electrodes in
All embodiments presented above could be also used for multiple stages of mass analysis in so-called MSn mode, where a precursor is selected by an ion gating arrangement, fragmented, and a fragment of interest is then optionally selected again and the process is repeated. An example is shown in
Use of two different flight paths through the spectrometer, at opposite injection angles, has been described earlier in relation to
In the embodiments of
Multi-reflection mass spectrometers of the present invention are image-preserving and may be used for simultaneous imaging or for image rastering at a speed independent of the time of flight of ions through the spectrometer.
In all embodiments of the present invention various known ion injectors may be used, such as an orthogonal accelerator, a linear ion trap, a combination of linear ion trap and orthogonal accelerator, an external storage trap such as is described in WO2008/081334 for example.
All embodiments presented above could be also implemented not only as ultra-high resolution TOF instruments but also as low-cost mid-performance analysers. For example, if the ion energy and thus the voltages applied do not exceed few kilovolts, the entire assembly of mirrors and/or compensation electrodes could be implemented as a pair of printed-circuit boards (PCBs) arranged with their printed surfaces parallel to and facing each other, preferably flat and made of FR4 glass-filled epoxy or ceramics, spaced apart by metal spacers and aligned by dowels. PCBs may be glued or otherwise affixed to more resilient material (metal, glass, ceramics, polymer), thus making the system more rigid. Preferably, electrodes on each PCB are defined by laser-cut grooves that provide sufficient isolation against breakdown, whilst at the same time not significantly exposing the dielectric inside. Electrical connections are implemented via the rear surface which does not face the ion beam and may also integrate resistive voltage dividers or entire power supplies.
For practical implementations the elongation of the mirrors in the drift direction Y should be minimised in order to reduce the complexity and cost of the design. This could be achieved by known means e.g. by compensating the fringing fields using end electrodes (preferably located at the distance of at least 2-3 times the height of mirror in Z-direction from the closest ion trajectory) or end-PCBs which mimic the potential distribution of infinitely elongated mirrors. In the former case, electrodes could use the same voltages as the mirror electrodes and might be implemented as flat plates of appropriate shape and attached to the mirror electrodes.
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” means “one or more”.
Throughout the description and claims of this specification, the words “comprise”, “including”, “having” and “contain” and variations of the words, for example “comprising” and “comprises” etc, mean “including but not limited to” and are not intended to (and do not) exclude other components.
It will be appreciated that variations to the foregoing embodiments of the invention can be made while still falling within the scope of the invention. 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 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.
Number | Date | Country | Kind |
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1201403.1 | Jan 2012 | GB | national |
The present application is a continuation under 35 U.S.C. § 120 and claims the priority benefit of co-pending U.S. patent application Ser. No. 14/852,466, filed Sep. 11, 2015, which is a continuation of U.S. patent application Ser. No. 14/374,214, filed Jul. 23, 2014, now U.S. Pat. No. 9,136,101, which is a National Stage application under 35 U.S.C. § 371 of PCT Application No. PCT/EP2013/051102, filed Jan. 22, 2013. The disclosures of each of the foregoing applications are incorporated herein by reference.
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Child | 15620255 | US | |
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Child | 14852466 | US |