High duty cycle ion spectrometer

What is claimed is: 1. An ion spectrometer, comprising: an ion source arranged to generate ions continuously; an ion selector device positioned to receive ions from the ion source and configured to select ions according to at least one characteristic thereof and to transmit the selected ions; an ion trap, arranged to receive the selected ions from the ion separation device along an axis, and to eject ions orthogonally to that axis, the ion trap being configured to eject ions having a range of mass to charge ratios narrower than the range of mass to charge ratios of the selected ions received from the ion separation device; a power supply, coupled to at least the ion trap so as to provide a potential causing ions selected by the ion selector device to continuously flow into the ion trap; and an ion analyser, arranged to receive ions ejected from the ion trap and separate the ions in accordance with at least one characteristic of the ions. 2. The ion spectrometer of claim 1 , wherein the ion selector selects ions according to their mass-to-charge ratios. 3. The ion spectrometer of claim 2 , wherein the ion selector is a quadrupole mass analyser. 4. The ion spectrometer of claim 2 , wherein the ion selector is a time-of-flight mass analyser. 5. The ion spectrometer of claim 2 , wherein the ion selector is a magnetic sector mass analyser. 6. The ion spectrometer of claim 1 , wherein the ion selector selects ions according to their mobilities. 7. The ion spectrometer of claim 1 , further comprising: ion optics, arranged to receive ions ejected from the ion trap and cool the ions; and wherein the ion analyser is arranged to receive ions from the ion optics. 8. The ion spectrometer of claim 7 , wherein the ion trap and ion optics share a common housing. 9. The ion spectrometer of claim 7 , wherein the ion trap comprises an exit slit and the ion optics comprises an entrance slit and wherein the exit slit of the ion trap is located adjacent the entrance slit of the ion optics. 10. The ion spectrometer of claim 7 , wherein the ion optics is arranged to receive ions from the ion trap along a primary axis and to eject ions along a secondary axis, the secondary axis being orthogonal to the primary axis. 11. The ion spectrometer of claim 1 , wherein the ion trap is further arranged to store the received ions and to continue to store any received ions that are not ejected. 12. The ion spectrometer of claim 1 , wherein the ion trap comprises a plurality of electrodes, the power supply being arranged to supply a DC potential, an RF potential and an excitation potential to the plurality of electrodes, the power supply being further arranged such that the excitation potential causes ions to be ejected from the ion trap. 13. The ion spectrometer of claim 1 , wherein the ion analyser comprises a sequential scanning mass filter, arranged to receive ions ejected from the ion trap and to transmit ions sequentially according to their mass to charge ratio. 14. A mass spectrometry method, comprising: generating ions continuously in an ion source; selecting ions generated at the ion source according to at least one characteristic thereof; passing the selected ions to an ion trap along an axis; ejecting ions from the ion trap orthogonally to the axis, wherein the ejected ions have a range of mass-to-charge ratios narrower than a range of mass-to-charge ratios of the selected ions; and receiving ions ejected from the ion trap at a mass analyser.