Gas retaining ion guide with axial acceleration

The invention claimed is: 1. A gas retaining ion guide comprising: a plurality of RF electrodes that extend from an entrance to an exit of the ion guide and are distributed about an ion region of the ion guide at different respective angular positions relative to a central axis such that, when different phases of a predetermined RF voltage are applied to adjacent RF electrodes, an RF electric field is generated that provides containment of ions in the ion region; and a plurality of DC electrodes that extend from the entrance to the exit of the ion guide and are distributed about the ion region at angular positions relative to the central axis that lie between the angular positions of the RF electrodes, each DC electrode having a conductive surface and providing a gas seal between two adjacent RF electrodes that inhibits gas flow out of the ion region in a radial direction, wherein at least some of the conductive surfaces of the DC electrodes have a radial distance from the central axis that changes between the entrance and exit of the ion guide. 2. The gas retaining ion guide of claim 1 wherein a common DC voltage is applied to each of the conductive surfaces of the DC electrodes. 3. The gas retaining ion guide of claim 1 wherein two of the DC electrodes on opposite sides of the central axis have conductive surfaces with a radial distance from the central axis that one of increases and decreases from the entrance to the exit of the ion guide. 4. The gas retaining ion guide of claim 3 wherein a DC voltage applied to the conductive surfaces of the DC electrodes has a polarity that is one of repelling and attracting to the ions in the ion guide, respectively. 5. The gas retaining ion guide of claim 1 wherein the DC electrodes are mounted between opposing slots in conductive material of adjacent RF electrodes. 6. The gas retaining ion guide of claim 1 wherein the conductive surfaces of the DC electrodes are further from the central axis than RF field generating surfaces of RF electrodes that contribute to the RF electric field in the ion region. 7. The gas retaining ion guide of claim 6 wherein each of the DC electrodes has a substantially oblong cross-sectional profile in a plane perpendicular to the central axis, and wherein the conductive surface of each DC electrode is perpendicular to a radial direction relative to the central axis. 8. The gas retaining ion guide of claim 7 wherein the RF field generating surfaces of two adjacent RF electrodes are separated by a gap that lies between the central axis and the conductive surface of a proximate one of the DC electrodes. 9. The gas retaining ion guide of claim 8 wherein the size of said predetermined gap is constant from the entrance to the exit. 10. The gas retaining ion guide of claim 8 wherein the size of the conductive surface of said proximate DC electrode is sufficient that it is intersected by any straight-line trajectory from the ion region that passes through the gap. 11. The gas retaining ion guide of claim 1 wherein the conductive surfaces of the DC electrodes have a minimum distance from any conductive surface of an RF electrode that is sufficient to prevent electrical arcing. 12. The gas retaining ion guide of claim 1 wherein each DC electrode comprises an insulating substrate on which its conductive surface is located. 13. The gas retaining ion guide of claim 12 wherein the conductive surface of each DC electrode covers only a portion of the substrate, and the substrate makes contact with conductive material of adjacent RF electrodes. 14. The gas retaining ion guide of claim 1 wherein a number of DC electrodes is such that a gas seal is provided between each two adjacent RF electrodes so that gas flow out of the ion region in all radial directions is inhibited. 15. An ion collision cell comprising the gas retaining ion guide of claim 14 . 16. The ion collision cell of claim 15 , further comprising a gas inlet located between the entrance and exit of the gas retaining ion guide, through which a collision gas is supplied to the ion region during operation. 17. A method of accelerating ions in a gas retaining ion guide comprising a plurality of RF electrodes that extend from an entrance to an exit of the ion guide and are distributed about an ion region of the ion guide at different respective angular positions relative to a central axis such that, when different phases of a predetermined RF voltage are applied to adjacent RF electrodes, an RF electric field is generated that provides containment of ions in the ion region, the method comprising locating a plurality of DC electrodes in the ion guide that extend from the entrance to the exit of the ion guide and that are distributed about the ion region at angular positions relative to the central axis that lie between the angular positions of the RF electrodes, each DC electrode having a conductive surface and providing a gas seal between two adjacent RF electrodes that inhibits gas flow out of the ion region in a radial direction, wherein at least some of the conductive surfaces of the DC electrodes have a radial distance from the central axis that changes between the entrance and exit of the ion guide. 18. The method according to claim 17 wherein locating a plurality of DC electrodes in the ion guide comprises locating two of the DC electrodes on opposite sides of the central axis that have conductive surfaces with a radial distance from the central axis that one of increases and decreases from the entrance to the exit of the ion guide. 19. The method according to claim 17 wherein locating a plurality of DC electrodes in the ion guide comprises mounting the DC electrodes between opposing slots in conductive material of adjacent RF electrodes. 20. The method according to claim 17 wherein each DC electrode comprises an insulating substrate on which its conductive surface is located, the insulating substrate making contact with conductive material of adjacent RF electrodes. 21. The method according to claim 17 wherein locating a plurality of DC electrodes in the ion guide comprises locating a number of DC electrodes in the ion guide that is sufficient to provide a gas seal between each two adjacent RF electrodes so that gas flow out of the ion region in all radial directions is inhibited.