The invention pertains to electrostatic dispersion lenses and ion beam dispersion methods.
U.S. Pat. No. 6,984,821, issued Jan. 10, 2006 to Appelhans et al., (hereinafter “Appelhans '821”) describes methods and apparatuses for increasing dispersion between ion beams. The goal of Appelhans '821 is to enhance the dispersion between ion beams, without regard to the energy of ions in the beams, where the beams were initially separated in space according to mass-to-charge ratio (m/z) by a magnetic sector field. Due to physical size constraints of ion detection technology, increasing dispersion of such mass separated beams is advantageous to simplify concurrent detection of the beams. The Appelhans '821 electrostatic dispersion lens (EDL) uses an electrostatic field shaped by two nested, one-quarter section, right cylindrical electrodes held at opposite voltages with a constant gap width between the cylindrical electrodes. At least
In one aspect of the invention, an EDL includes a case surface and at least one electrode surface. The EDL is configured to receive through the EDL a plurality of spatially separated ion beams, to generate an electrostatic field between the one electrode surface and either the case surface or another electrode surface, and to increase the separation between the beams using the field. Other than an optional mid-plane intended to contain trajectories of the beams, the electrode surface or surfaces do not exhibit a plane of symmetry through which any beam received through the EDL must pass.
In another aspect of the invention, an EDL includes a case surface and at least one electrode surface. The EDL is configured to receive through the EDL a plurality of spatially separated ion beams, to generate an electrostatic field between the one electrode surface and either the case surface or another electrode surface, and to increase the separation between the beams using the field. The one electrode surface and either the case surface or the other electrode surface have geometries configured to shape the field to exhibit a less abrupt entrance and/or exit field transition in comparison to another electrostatic field. The other electrostatic field is shaped by two nested, one-quarter section, right cylindrical electrode surfaces held at opposite voltages with a constant gap width between the cylindrical electrode surfaces.
Preferred embodiments of the invention are described below with reference to the following accompanying drawings.
As is apparent from
Graphically speaking, beam 110d drops down to a low position on energy surface 106 upon entering the field transition region. Conversely, beam 110a rises up to a high position on energy surface 106. Due to their simulated position on energy surface 106, beams 110a-110d are turned different amounts. Literally speaking, the beams' positions within the electrostatic field may differentially change the kinetic energy, and thus the trajectory, of the beams while in the field. However, in actuality, the change in trajectory does not mean that the beams move up or down out of the z-axis focus plane as shown in
Upon exiting through another field transition region, as shown graphically in
The field transition regions onto and off of energy surface 106 are shown in
Despite the enhanced dispersion shown in
Since beam dispersion may alleviate size constraints in ion detection equipment, beam broadening might reduce the potential advantage of dispersing beams by pushing detection equipment back into closer proximity to encompass the entire beam width. A first ratio of beam spacing relative to beam width may exist at the input to the EDL and a second ratio of beam spacing relative to beam width may exist after the output from the EDL at the point of detection. Dispersion of beams acts to make the second ratio larger than the first ratio, but broadening of beams counteracts the increase and brings the second ratio back closer to or less than the first ratio. Ultimately, at the point of detecting dispersed beams, if the second ratio is greater than or equal to the first ratio, then the EDL might function to relieve physical constraints in ion detection equipment. Even if the ratio stays constant, when the beam width is within the requirements of the detector and the detectors can fit between the dispersed beams, then an advantage of dispersing beams might be achieved. Variability in beam broadening may produce differences in selecting the size and/or configuration of detection equipment depending on the extent of broadening and, thus, might further complicate ion detection.
Observation indicated the existence of competing design goals for an EDL. Primary design goals include avoiding variance in beam-to-beam dispersion when at least three beams are present while providing the widest angular dispersion, avoiding divergence of beam profiles (beam broadening), and improving z-axis focusing of the beams. A series of SIMION simulations were conducted, exploring EDL designs alternative to the Appelhans design of U.S. Pat. No. 6,984,821 for which a SIMION simulation is shown in
The Appelhans '821 EDL uses two nested, one-quarter section, right cylindrical electrode surfaces held at opposite voltages with a constant gap width between the cylindrical electrode surfaces. Reference herein to such electrode surfaces as one-quarter section, right cylindrical electrode surfaces describes only the surfaces of such electrodes from which the electrostatic field employed in dispersing ion beams is generated. The geometry of such surfaces may be appreciated throughout Appelhans '821, in particular,
Instead of using a symmetrical cylindrical EDL, asymmetrical designs may provide an EDL improving performance of one or more of the competing design goals discussed above in comparison to the Appelhans '821 EDL. As will be appreciated from the description herein, selected asymmetries may be used to tailor a particular EDL design to provide significant improvement in achieving one or two of the design goals, while perhaps not addressing another design goal in comparison to the Appelhans '821 symmetrical cylindrical EDL. Depending on the system in which the EDL is used, the design goal(s) of particular importance may be selected for enhancement, perhaps at the intended sacrifice of improving or even conserving performance of other design goals of less importance in the context of the particular system.
According to one aspect of the invention, an EDL includes a case surface and at least one electrode surface. The EDL is configured to receive through the EDL a plurality of spatially separated ion beams, to generate an electrostatic field between the one electrode surface and either the case surface or another electrode surface, and to increase the separation between the beams using the field. Other than an optional mid-plane intended to contain trajectories of the beams, the electrode surface or surfaces do not exhibit a plane of symmetry through which any beam received through the EDL must pass.
By way of example, the EDL may be configured to receive the beams with equal kinetic energies upon entering the field. Also, the one electrode surface and either the case surface or the other electrode surface may have geometries configured to shape the field to exhibit a less abrupt entrance and/or exit field transition in comparison to another electrostatic field. Such other electrostatic field may be shaped by two nested, one-quarter section, right cylindrical electrode surfaces held at opposite voltages with a constant gap width between the cylindrical electrode surfaces. Appelhans '821 generates one such electrostatic field. However, in the aspects of the invention herein, geometries may be selected to control the field transition so that certain design goals may be addressed. An EDL with a controlled field transition may exhibit properties not previously addressed in known electrostatic fields.
A variety of uses may exist for the controlled field transition EDL in the present aspect of the invention as well as other aspects of the invention, including use in a mass spectrometer, as described in Appelhans '821. Another possible application includes use in mass separators. Mass separators may exist in various types of specialized processing equipment used to produce quantities of mass separated elements or molecular species collected for future use. Mass spectrometers for multiple-isotope elements are used in a variety of applications ranging from geochronology to nuclear forensics.
Even though separation may be accomplished with a magnetic sector field, other separation methods and/or apparatuses may be used. Ion beams separated by any means and having the same energy may function in the controlled field transition EDL in the same manner as described for mass separated beams. The controlled field transition EDL is mass independent. Thus, no requirement exists that the beams be mass separated or otherwise contain segregated ions of different masses. Consequently, applications beyond mass spectrometry may exist. Suitable applications include those producing two or more beams containing ions having the same charge, both in quantity (that is, singly charged, doubly charged, etc.) and polarity (that is, all positive or all negative), where dispersion between the beams is desired.
A variety of possible asymmetrical designs exist. Some designs, such as those described herein, perform better at achieving one or more of the competing design goals for an EDL in comparison to other asymmetrical designs. For example, the at least one electrode surface mentioned above may be an outer electrode surface including a one-quarter section, right cylindrical electrode surface as the one electrode surface. The other electrode surface mentioned above may be a nested inner electrode surface including a one-quarter section, right cylindrical portion and a tangential extension portion. The extension portion may be positioned at an entrance to the field and a constant gap width may exist between the outer electrode surface and the cylindrical portion of the inner electrode surface.
Outer electrode 202 includes a one-quarter section, right cylindrical electrode surface 230. Inner electrode 204 includes an electrode surface with a one-quarter section, right cylindrical portion 232 and a tangential extension portion 234. Extension portion 234 is positioned at what will become an entrance to an electrostatic field generated between outer electrode surface 230 and cylindrical portion 232/tangential portion 234. A constant gap width exists between outer electrode surface 230 and cylindrical portion 232 of inner electrode 204.
A field transition region exists where beams 210a-g move onto the slope of energy surface 226 and some beams move above or below mid-plane 228. The field transition region simulates beams 210a-g entry into an electrostatic field as described with regard to
Essentially eliminating the exit focus significantly narrowed beams 210a-g in the dispersion direction compared to beams 110a-d. Consequently, the SIMION output also showed that a ratio of beam spacing-to-beam width improved to approximately 15:1 in the controlled field transition EDL of
As is readily apparent, other than mid-plane 208 intended to contain trajectories of beams 210a-g, electrode surface 230, cylindrical portion 232, and tangential portion 234 in combination do not exhibit a plane of symmetry through which any beam received through the EDL must pass. The introduced asymmetries thus address the primary design goals discussed above. Even though the design does not improve z-axis focusing, it is conserved.
Magnetic sector 218 includes a standard double dispersion magnet, which has a magnet focal plane exhibiting a considerable “tilt.” The tilt refers to the focal point of the lighter m/z 238 ion beam (beam 210g) occurring at a different point along the beams' trajectory in comparison to the focal point for the m/z 244 ion beam (beam 210a). In other words, due to the magnetic field, a line connecting the focal points of the beams is not perpendicular to the beams' trajectory, but is instead “tilted” at a non-normal angle to the beams' trajectory. In Appelhans '821, positioning an EDL such that the beams' focal points occur just prior to entering the electrostatic field of the EDL appeared to produce the best results. If the Appelhans '81 EDL was positioned with the focal point of beam 210a at the optimum distance into the EDL, then the focal point of beam 210g fell short of the EDL.
Modifying the Appelhans '821 EDL by extending inner electrode 204 toward entrance aperture 212 allows beam 210g containing m/z 238 to be shaped by the electrostatic field sooner, which avoids divergence of the beam 210g profile without degrading the beam 210a profile containing m/z 244. One of the competing design goals described above includes providing electrode surfaces configured to shape an electrostatic field to avoid divergence of beam profiles. By avoiding beam profile divergence, the modification in the example shown in
As may be appreciated from the discussion above, another aspect of the invention involves an EDL including a case surface and at least one electrode surface. The EDL is configured to receive through the EDL a plurality of spatially separated ion beams, to generate an electrostatic field between the one electrode surface and either the case surface or another electrode surface, and to increase the separation between the beams using the field. The one electrode surface and either the case surface or the other electrode surface have geometries configured to shape the field to exhibit a less abrupt entrance and/or exit field transition in comparison to another electrostatic field. The other electrostatic field is shaped by two nested, one-quarter section, right cylindrical electrode surfaces held at opposite voltages with a constant gap width between the cylindrical electrode surfaces.
By way of example, the EDL may be configured to receive the beams with equal kinetic energies upon entering the field. In keeping with the design goals described herein, the geometries of the one electrode surface and either the case surface or the other electrode surface may be configured to shape the field to avoid variance in beam-to-beam dispersion when at least three beams are present. Also, the geometries of the one electrode surface and either the case surface or the other electrode surface may be configured to shape the field to avoid divergence of beam profiles. Further, the geometries of the one electrode surface and either the case surface or the other electrode surface may be configured to shape the field to conserve or improve on z-axis focusing of the beams.
The EDL includes an entry/exit aperture 312 to receive ion beams 310. Due to the extremely wide angular dispersion of beams 310, they also exit the EDL through the wide slot in the EDL forming entry/exit aperture 312. As will be appreciated, applying a potential of +10,000 volts to electrode 302 while case 306 (including rod 308) is at ground potential (10,000 volts difference) may generate an electrostatic field sufficient to disperse 5 kV ion beams in the manner shown in
While the simulation shown in
The simulation revealed that some of beams 310 exhibit beam broadening. Also,
Z-axis focusing of the beams represents another design consideration. The EDL of
The tradeoffs among the competing design goals for an EDL are apparent in the embodiment of
An entry/exit aperture 412 is provided to receive ion beams 410. Due to the extremely wide angular dispersion of beams 410 they also exit the EDL through entry/exit aperture 412. As will be appreciated, applying a potential of +10,000 volts to electrode 402 while case 406 is at ground potential (10,000 volt difference) may generate an electrostatic field sufficient to disperse 5 kV ion beams in the manner shown in
Similar to the ellipsoid EDL, the cuboid EDL of
In addition to the various apparatuses described herein, aspects of the invention also include ion beam dispersion methods. According to one aspect of the invention, a dispersion method includes providing a plurality of spatially separated ion beams and directing the beams through an EDL including a case surface and at least one electrode surface. The method includes generating an electrostatic field between the one electrode surface and either the case surface or another electrode surface and increasing the separation between the beams using the field. Other than an optional mid-plane containing intended trajectories of the beams, the electrode surface or surfaces do not exhibit a plane of symmetry through which any beam received through the EDL must pass.
By way of example, the beams may have equal kinetic energies upon entering the field. Also, generating the field may include applying to the one electrode a voltage different from either a voltage of the case surface or a voltage of the other electrode surface. The case surface may be operated at ground potential. The one electrode surface and either the case surface or the other electrode surface may have geometries that shape the field to exhibit a less abrupt entrance and/or exit field transition in comparison to another electrostatic field shaped by two nested, one-quarter section, right cylindrical electrode surfaces held at opposite voltages with a constant gap width between the cylindrical electrode surfaces.
According to another aspect of the invention, a dispersion method includes providing a plurality of spatially separated ion beams and directing the beams through an EDL including a case surface and at least one electrode surface. The method includes generating an electrostatic field between the one electrode surface and either the case surface or another electrode surface and increasing the separation between the beams using the field. The electrostatic field is shaped by geometries of the one electrode surface and either the case surface or the other electrode surface. The geometries shape the field to exhibit a less abrupt entrance and/or exit field transition in comparison to another electrostatic field shaped by two nested, one-quarter section, right cylindrical electrode surfaces held at opposite voltages with a constant gap width between the cylindrical electrode surfaces.
By way of example, the geometries of the one electrode surface and either the case surface or the other electrode surface may shape the field and avoid variance in beam-to-beam dispersion when at least three beams are present. Also, the geometries of the one electrode surface and either the case surface or the other electrode surface may shape the field and avoid divergence of beam profiles. Further, the geometries of the one electrode surface and either the case surface or the other electrode surface may shape the field and conserve or improve on z-axis focusing of the beams. Other operational parameters discussed herein regarding other aspects of the invention may be implemented in the controlled field transition method of the present aspect of the invention.
In compliance with the statute, the invention has been described in language more or less specific as to structural and methodical features. It is to be understood, however, that the invention is not limited to the specific features shown and described, since the means herein disclosed comprise preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims appropriately interpreted in accordance with the doctrine of equivalents.
The United States Government has certain rights in this invention pursuant to Contract No. DE-AC07-05ID14517 between the United States Department of Energy and Battelle Energy Alliance, LLC.