This patent application claims priority from German Patent Application 10 2010 006 449.1 filed on Feb. 1, 2010 and German Patent Application 10 2010 013 546.1 filed on Mar. 31, 2010, each of which is hereby incorporated by reference.
This invention relates generally to ion manipulation cells and, more particularly, to manipulating guidance, focusing, bunching, storage, reactive change, and/or mass measurement via oscillations of ions using elongated RF ion cells with radial and axial potential profiles.
Researchers have long been searching for RF multipole systems with axially superimposed electric potential profiles for the manipulation of ions in different ways, for example guiding the ions through sections of instruments (“ion guides”), even against flows of gas molecules. The ions may be manipulated, for example, for generation of longitudinal oscillations of the ions, for production of finely focused ion beams, for reactions between ions of opposite polarity, and/or for fragmentation and thermalization of ions. Ideally, axially superimposed electric potential profiles may be switched between different profile shapes. In addition to temporarily storing and thermalizing ions, such multipole systems should be able to, for example, fragment the ions via collisions with collision gas molecules and subsequently or simultaneously transport the fragmented ions to an exit at an end of the multipole system.
A “two-dimensional multipole field” may be defined as a field generated by alternatively applying two different voltages to two or more pairs of pole rods included in a multipole system. The voltages may be DC voltages or AC voltages. Effective radially repelling pseudoforces for ions, however, typically only occur with RF voltages.
Pole rods of a multipole system may be cylindrical sheath segments, rectangular plates, round rods or hyperbolic rods, depending on the desired quality of the multipole field. An ideal multipole field is generated in the vicinity of an axis, but typically only extends radially up to the pole rods when the pole rods have a certain hyperbolic shape. The multipole field may deviate for other shapes more or less strongly from the ideal multipole field, the greater the distance from the axis, which particularly affects the repulsive forces of the pseudopotential.
The radially repulsive pseudoforce produced by the pseudopotentials is typically strongest for RF quadrupole electrode systems having two pairs of pole rods. The ions in such quadrupole systems are trapped in a virtual tube, figuratively speaking, by repulsive pseudoforces which increase radially in each direction. The ions may move freely in the axial direction without an axial potential gradient; i.e., the ions are not trapped in the axial direction. The ions may oscillate freely about the axis with so-called “secular oscillations” under high vacuum conditions. The ion oscillations may be damped by collisions, however, in a medium vacuum, where the ions collect on the axis. The aforesaid process may be referred to as “collision focusing” or “thermalization” of the ions. Quadrupole systems with a linear potential drop along the axis correspond to sloping tubes where the content flows in one direction under the influence of the slope. They therefore form an “ion chute”. Multipole systems with larger numbers of rod pairs, such as hexapole or octopole rod systems, have lower radially repulsive pseudoforces, but also form such tubes for ions. Axial potential profiles in such systems may also transmit or trap ions as a function of the shape of the profile.
A longitudinal electric field may be superimposed by producing a quadrupole electrode system out of four resistance wires, across each of which a DC voltage drop is generated in the same direction. The wires carry a relatively high RF voltage to generate the quadrupole RF field because the largest voltage drop occurs in the immediate vicinity of each wire. Resistance of each wire should not be particularly high because, otherwise, the RF alternating voltage cannot propagate quickly enough along the wires. Relatively small DC voltage drops therefore are typically generated along each wire. It may also be difficult to generate desired profiles of the DC electric field which are not simply linear voltage gradients along the axis. Ions may also be able to easily escape because the pseudopotential barrier between the wires is relatively low.
A longitudinal electric field may also be superimposed using a quadrupole system having a large number of parallel wires mounted so as to reproduce four hyperbolic surfaces of an ideal quadrupole system. Such a hyperbolic quadrupole system reproduced with wires was developed approximately 50 years ago by the research group of Wolfgang Paul. While quadrupole systems are difficult to produce and may be imprecise, they do provide a simple way of generating an axial DC field by generating voltage drops across the wires.
Other ion storage systems which have an electrically switched forward feed are disclosed in U.S. Pat. No. 5,572,035 to Franzen. The '035 patent discloses, for example, a system that includes two helically coiled conductors in a shape of a double helix, and operated by being connected to two phases of an RF voltage. The '035 patent also discloses a system including coaxial rings to which the phases of an RF AC voltage are alternately connected. Both systems may be operated to generate an axial feed of the ions. The double helix may be made from resistance wires across which a DC voltage drop is generated. The individual rings of the ring system may be supplied with a DC potential that changes from ring to ring. This may also be used to tailor desired shapes of axial potential profiles.
U.S. Pat. No. 5,847,386 to Thomson et al. discloses methods for generating an axial voltage drop in quadrupole round rod systems. In one embodiment, the quadrupole system is divided up into a large number of axially separated segments. The '386 patent also discloses penetrating resistance layers carrying a DC voltage drop with RF fields as DC potentials are introduced into the quadrupole rod system from the outside by surrounding electrodes.
U.S. Pat. No. 7,164,125 to Franzen et al. discloses generating axial DC potential profiles by insulated resistance layers.
Each of the aforesaid techniques, however, has various drawbacks. The disclosed systems, for example, may not provide ideal potential profiles, may be difficult to manufacture, and/or may not be switchable or adjustable.
In addition to the generation of axial DC voltage profiles in multipole systems, the generation of axial pseudopotential profiles is also of great interest. If one disregards very weak pseudopotential gradients in conical multipole rod systems, only pseudopotential barriers at the ends of multipole systems have been described up to now.
There is a need in the art therefore for elongated ion cells with electrically adjustable shapes of radial and axial distributions of DC potentials and pseudopotentials.
According to an aspect of the invention, an ion cell having an axis includes a sheath of individual electrodes that extends along the axis and defines an internal volume. Adjacent individual electrodes are electrically insulated from each other. The individual electrodes each receive a DC potential and RF voltage. At least some of the individual electrodes have a width that varies in the axial direction such that an electrical effect on an axis potential varies along the axis of the ion cell.
According to another aspect of the invention, a method is provided for using an ion cell having an axis, where the ion cell includes a sheath of individual electrodes that extends along the axis defining an internal volume, where adjacent individual electrodes are insulated from each other, and where at least some of the individual electrodes have a width that varies in the axial direction such that an electrical effect on an axis potential varies along the axis of the ion cell. The method includes providing a DC potential and a RF voltage to each of the individual electrodes.
According to another aspect of the invention, an ion cell includes an elongated interior volume surrounded by a pattern of individual electrodes. The individual electrodes are insulated from one another via, for example, insulating gaps. The insulating gaps do not predominantly run parallel to the axis. The individual electrodes may taper and/or widen as they extend in a longitudinal direction. The term “elongated interior volume” describes how the interior volume of the ion cell is longer in one direction than in the others. A longitudinal axis therefore extends between two ends of the ion cell along the longitudinal direction.
The individual electrodes may be supplied (e.g., in longitudinal groups) with different mixtures of DC and RF voltages. Both arbitrary radially storing pseudopotentials and arbitrary axial profiles of the DC potentials and pseudopotentials therefore may be generated. The potential profiles may be arbitrarily changed by changing the electric voltages supplied thereto. The individual electrodes of the ion cell may be shaped such that their respective electrical effect on the axis potential varies along the longitudinal axis. The individual electrodes may be supplied with electric potentials that generate not only radially repulsive potential profiles, but also different shapes of axial profiles of DC potentials and pseudopotentials, including potential wells or unidirectional potential gradients.
The interior volume may have any shape; e.g., an ellipsoid that is cut off at both ends, a truncated cone or a cylinder with a round, square or polygonal base.
A subgroup of individual electrodes may extend between two ends of the ion cell when the internal volume is a cylinder. The subgroup as a whole may have substantially the same width along substantially its entire length. Such a subgroup may be referred to as a “longitudinal group”. A longitudinal group may be thought of as a rod electrode of a multipole rod system, which is divided into a plurality of insulated individual electrodes of varying width. The individual electrodes may be divided via slanted, straight and/or curved cuts. The envelope of the longitudinal group may have any form; e.g., a cylindrical surface segment, rectangular plate, round rod or a hyperbolic rod.
Each of the longitudinal groups of the ion cell may have substantially the same shape, and the individual electrodes may be arranged in substantially the same pattern. Individual electrodes that have the same shape at corresponding locations of the different longitudinal groups may be referred to as “corresponding individual electrodes”.
An ion cell may include at least two pairs of longitudinal groups. Each longitudinal group may be constructed in a similar manner from individual electrodes and may be arranged symmetrically around the longitudinal axis. The individual electrodes of one longitudinal group may be supplied with an RF voltage having substantially the same frequency, amplitude and phase, where phase and opposite phase may alternate from longitudinal group to longitudinal group. Such an ion cell may be thought of as a multipole rod system whose pole rods have each been divided into individual electrodes by slanted (e.g., not parallel to the longitudinal axis), straight or curved cuts.
If an axial profile is produced from DC potentials in such a cell, the individual electrodes of a longitudinal group are each provided with different DC potentials. A potential profile in the interior of the cell which varies in the axial direction and is radially symmetric may be provided when corresponding individual electrodes are applied with the same DC potentials. Switchable DC potentials allow ions to, for example, be either stored in potential wells or ejected in the axial direction.
Axial profiles of the pseudopotentials may also be generated when individual electrodes of a longitudinal group are each supplied with RF voltages of substantially the same frequency and phase, but with different amplitudes. Both positive and negative ions may be stored in axial wells of such pseudopotentials. Similarly, the superposition of RF voltages with different frequency, amplitude or phase at a corresponding set of individual electrodes may produce an axial profile of the pseudopotentials.
Ion cells may be provided for collisionally induced fragmentation (CID) with the possibility of fast axial ejection of the product ions. Ion cells may be provided for reactions between positive and negative ions; e.g. for a fragmentation by electron transfer (ETD). Ion cells may be provided for the ejection of ions with temporal focusing of ions of the same mass (bunching effect). Ion cells may be provided for the ejection of ions with temporal and spatial focusing for each mass. Ion cells may be provided for ejection of the ions against a gas flow with measurement of their mobility. Ion cells may also be provided for a Fourier transform mass spectrometer with measurement of axial oscillations of the ions in a harmonic field.
These and other objects, features and advantages of the present invention will become more apparent in light of the following detailed description of preferred embodiments thereof, as illustrated in the accompanying figures.
Each of the individual electrodes 20a-20e may be supplied with an independent mixture of DC and RF voltages such that diverse distributions of both the DC potential and the RF pseudopotential may be created within the ion cell 12. Potential profiles of almost any shape, defined for example by Laplace equations, may be generated along the longitudinal axis 16.
The individual electrodes in each longitudinal electrode may form a “longitudinal group”. Each longitudinal group of individual electrodes extends between two ends of the ion cell 24, and may have a substantially constant width. The ion cell 24 in
Referring to
The individual electrodes may be discretely manufactured and subsequently assembled to form in an electrode sheath and/or longitudinal groups.
The individual electrodes in each longitudinal group may be arranged in a uniform pattern as shown in
Axial profiles of pseudopotentials are generated in the interior of the ion cell when the individual electrodes of a longitudinal group are not supplied with the same RF voltages. The individual electrodes, for example, may be supplied with RF voltages having different amplitudes and/or frequencies.
Referring again to
Referring to
The multipole ion cell 36 with the individual electrodes in zigzag form may be manufactured using electronic circuit boards, metalized glass, ceramic or glass-ceramic plates. The rectangular pole plates of the quadrupole rod system are each divided by zigzag cuts into longitudinal groups, each having three individual electrodes. At the two ends and in the middle, an individual electrode extends substantially the entire width of the longitudinal group. By supplying the individual electrode with RF and DC voltages, similar to the supply shown in
Referring still to
The ion cell 36 may be manufactured by fixing the individual electrodes to a surrounding, insulating mounting frame (not shown), for example, made of glass, ceramic or plastic. It may be simpler to use electronic circuit boards, however, on which the individual electrodes of a longitudinal group are produced via etching metal layers. Increasing the number of zig-zag paths may improve the performance of the cell. The ion cell may alternatively be manufactured using glass, ceramic or glass-ceramic plates metalized on one side. The metal layers are divided into the individual electrodes of a longitudinal group by milling or sawing. Where a diamond-coated wire is used for sawing the metalized plates, for example, the cut may be relief milled so deeply that it is of hardly any consequence if impacting ions charge up the insulating body.
Referring to
The magnet 62 maintains ions in the ion cell 60 on the longitudinal axis. The magnetic field, for example, runs parallel to the longitudinal axis of the cell 60 such that ions experience at least a time-averaged parabolic potential (see
Referring again to
The modulation of the DC field away from the axis may be reduced by including a larger number of individual electrodes. For example,
Each longitudinal group in the ion cell 84 extends along a centerline (not shown) such that none of the separating gaps are parallel to the axis 94. The individual electrodes (e.g., 86a-c and 88a-c) may, however, be grouped together to form equally wide, slightly twisted, longitudinal groups 86 and 88 which, like the electrodes in their counter-groups 90 and 92, are supplied with substantially the same RF voltage. The slight twisting of the RF quadrupole field in the interior has hardly any negative effect. The slight twisting, however, may balance out the modulation. Embedding the ion cell 84 into an axial magnetic field may improve the coherence of the oscillations for ions having substantially the same mass.
In some embodiments, half the ion cell shown in
Some applications may use a one-sided forward drive of the ions. Such a one-sided forward drive may be achieved with the ion cell 24 in
When the collision-focusing RF field is as ideal as possible away from the axis, hyperbolic pole rods may be used that are cut into longitudinal groups with individual electrodes by straight or curved cuts.
The individual electrodes of a longitudinal group in the ion cell 24 in
Positive and negative ions may be stored in the ion cell 108 at the same time to, for example, fragment multiply positively charged analyte ions by electron transfer dissociation (ETD). The fragment ions that collect in the center of the cell may be ejected from the cell by applying a DC voltage gradient, and guided to a mass analyzer.
A time-of-flight mass spectrometer with orthogonal ion injection may be used for the mass analysis. Orthogonal ion injection requires a narrow ion beam into a pulser, which pulses out segments from the ion beam perpendicular to the previous direction of flight of the ions and into the flight tube. The time of flight of these ions is measured. Ions of all masses of interest may be included in the narrow beam at the time the pulsing out occurs. If the operation for the fragmentation is intermittent, however, a simple ejection of the ions from the fragmentation cell may provide mass discrimination because of the different flight times to the pulser; i.e., the pulser does not contain ions of different masses simultaneously.
Mass discrimination may be compensated for with the system in
A temporal ion focusing for ions of different masses may also be provided by applying counteracting axial pseudopotentials and DC potentials. Heavy ions are driven further into the pseudopotential than light ones because the pseudopotential has a mass-dependent effect, whereas the DC potential does not. The mass-dependent spatial distribution of the ions may then be used during an ejection such that heavy ions and light ions arrive at substantially the same time in the pulser of the time-of-flight mass spectrometer.
In the system shown in
The ion cell 126 with this type of electrical configuration represents a type of ion cell for universal use. It may be used, for example, with a DC voltage well for collision-induced fragmentation rather that a pseudopotential well. Positive and negative ions may be stored at the same time, however, with the pseudopotential well for a fragmentation of multiple positively charged ions by electron transfer (ETD) from suitable negative reaction ions. When the ion cell 126 is operated with an adjustable pseudopotential well, stray fields at the ends of the ion cell are not changed. Neither the injection conditions nor the effects on adjacent systems therefore change. Both a DC voltage well and an ion chute may be generated by the DC potentials Ua, Ub and Uc. An adjustable interaction of ion slide and pseudopotential well allows the ions to be ejected mass-sequentially, where heavy ions are ejected first. The ion cell may therefore generate a very fine ion beam, as is used for time-of-flight mass spectrometers with orthogonal ion injection.
The descriptions provided above have focused on multipole-type ion cells with symmetrically arranged longitudinal groups and straight longitudinal axis. With knowledge of this invention, those skilled in the art will be able to develop many further advantageous embodiments of ion cells and their electrical configurations for many different types of applications, for example banana-shaped or semi-circular ion cells with potential gradients, ion cells for the radial ejection of the ions, ion cells with several DC potential or pseudopotential wells to store different types of ions at different locations, and many more. Various changes, omissions and additions to the form and detail the disclosed invention therefore may be made therein without departing from the spirit and scope of the invention.
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10 2010 006 449 | Feb 2010 | DE | national |
10 2010 013 546 | Mar 2010 | DE | national |
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