Ion transfer method and device

What is claimed is: 1. An ion transport device of a mass spectrometer, comprising: a plurality of pole rod pairs arranged in parallel, the pole rod pairs defining a plurality of ion transport cells, each ion transport cell uniquely corresponding to a contiguous group of a fixed number of pole rod pairs, such that no two ion transport cells share a common pole rod pair; and a controller configured to apply voltages in a repeating voltage pattern to the pole rod pairs thereby creating a plurality of potential wells capable of capturing ions, wherein each ion transport cell receives the same pattern of voltages; apply RF potentials to the pole rods such that each pole rod pair includes a first pole rod having a RF+ polarity and a second pole rod having an RF− polarity; move the repeating voltage pattern along the pole rod pairs to move captured ions within and between the plurality of ion transport cells along the ion transport device; and apply at least one ejection voltage to one or more electrodes to cause ions to be ejected from the ion transport device in a direction parallel to the pole rods. 2. The ion transport device of claim 1 , wherein the spacing between pole rods of a pole rod pair is greater than the spacing between pole rod pairs. 3. The ion transport device of claim 1 , wherein the spacing between pole rod pairs is substantially equal along the length of the ion transport device. 4. The ion transport device of claim 1 , wherein the spacing between pole rods of a pole rod pair is between two and four times greater than the spacing between pole rod pairs. 5. The ion transport device of claim 1 , wherein the repeating voltage pattern is a stepped voltage pattern. 6. The ion transport device of claim 1 , wherein the repeating voltage pattern is a pattern of continuously varying voltage levels. 7. The ion transport device of claim 1 , wherein the ion transport device is positioned and oriented to receive ions in a direction parallel to the primary axes of the pole rods. 8. A mass spectrometer, comprising: an ion transport device including a plurality of pole rod pairs arranged in parallel, the pole rod pairs defining a plurality of ion transport cells, each ion transport cell uniquely corresponding to a contiguous group of a fixed number of pole rod pairs, such that no two ion transport cells share a common pole rod pair; and a controller configured to apply voltages in a repeating voltage pattern to the pole rod pairs thereby creating a plurality of potential wells capable of capturing ions, wherein each ion transport cell receives the same pattern of voltages; move the repeating voltage pattern along the pole rod pairs to move captured ions within and between the plurality of ion transport cells along the ion transport device; and apply at least one ejection voltage to one or more electrodes to cause ions to be ejected from the ion transport device in a direction parallel to the pole rods, wherein the ion transport device is positioned and oriented to receive ions travelling in a direction parallel to the primary axes of the pole rods. 9. The mass spectrometer of claim 8 , wherein the ions are transported along the ion transport device in a direction perpendicular to the primary axes of the pole rods. 10. The mass spectrometer of claim 8 , wherein the spacing between pole rods of a pole rod pair is greater than the spacing between pole rod pairs. 11. The mass spectrometer of claim 8 , wherein the spacing between pole rod pairs is substantially equal along the length of the ion transport device. 12. The mass spectrometer of claim 8 , wherein the spacing between pole rods of a pole rod pair is between two and four times greater than the spacing between pole rod pairs. 13. The mass spectrometer of claim 8 , wherein the repeating voltage pattern is a stepped voltage pattern. 14. The mass spectrometer of claim 13 , wherein the stepped voltage pattern is a pattern of High-Low-High applied across three pole rod pairs. 15. The mass spectrometer of claim 13 , wherein the stepped voltage pattern is a pattern of High-Low-Low-High applied across four pole rod pairs. 16. The mass spectrometer of claim 13 , wherein the stepped voltage pattern is a pattern of High-Low-Low-Low-High applied across five pole rod pairs. 17. The mass spectrometer of claim 8 , wherein the repeating voltage pattern is a pattern of continuously varying voltage levels. 18. The mass spectrometer of claim 17 , wherein the pattern of continuously varying voltage levels is applied across three pole rod pairs and is defined by V1(t)=+V*cos(Pi/4−ω*t), V2(t)=−V*cos(Pi/4−ω*t), V3(t)=+V*cos(Pi/4−ω*t). 19. The mass spectrometer of claim 17 , wherein the pattern of continuously varying voltage levels is applied across four pole rod pairs and is defined by V1(t)=V*cos(ω*t−Pi/4), V2(t)=V*sin(ω*t−Pi/4), V3(t)=−V*cos(ω*t−Pi/4), V4(t)=−V*sin(ω*t−Pi/4). 20. The mass spectrometer of claim 17 , wherein the pattern of continuously varying voltage levels is applied across five pole rod pairs and is defined by V1(t)=V*cos(ω*t−Pi/5), V2(t)=−V*cos(ω*t+(2/5)*Pi), V3(t)=−V*cos(ω*t), V4(t)=−V*cos(ω*t−(2/5)*Pi), V5(t)=V*cos(ω*t+Pi/5).