Patent Number: 
Section: claims

1. A focused ion beam system, comprising:an inductively coupled plasma ion source;a source biasing electrode at the plasma ion source;an electrical connection to the source biasing electrode;a focused ion beam column, configured to focus an ion beam at the sample;a source biasing power supply having a dc voltage output;a first circuit coupling the dc voltage from the source biasing power supply to the source biasing electrode;one or more lenses; anda plurality of apertures, wherein one or more apertures within the plurality of apertures has a material composition selected for low sputtering, the material composition comprising one or more of the following: carbon-based compounds, beryllium, vanadium, titanium, scandium, silicon, or niobium. 2. The focused ion beam system of claim 1, further comprising a plasma sensor for detecting the presence of a plasma within the ion source. 3. The focused ion beam system of claim 2, further comprising:logic circuitry electrically connected to receive a signal from the plasma sensor; andan electrical control connection from the logic circuitry to the plasma igniter. 4. The focused ion beam system of claim 3 wherein the logic circuitry is configured to control the plasma igniter based on a signal from the plasma detector. 5. The focused ion beam system of claim 1, further comprising a vacuum enclosure, wherein the vacuum enclosure contains the inductively coupled plasma ion source, and wherein the plasma igniter is mounted at or near the exterior of the vacuum enclosure 6. The focused ion beam system of claim 1, wherein the inductively coupled plasma ion source further comprises:an insulating plasma chamber;an RF antenna surrounding the plasma chamber;a match box electrically connected to the RF antenna;an RF power supply electrically connected to the match box; anda gas feed system configured to supply a feed gas for ionization into the plasma chamber. 7. The focused ion beam system of claim 1 wherein the plasma chamber includes an insulating plasma chamber comprising one or more of the following: ceramic, quartz, or machinable ceramic. 8. The focused ion beam system of claim 1, further comprising:a plasma igniter having a pulsed voltage waveform; anda second circuit coupling the pulsed voltage waveform from the plasma igniter to the source biasing electrode. 9. A method of processing a sample with a focused ion beam system having an inductively couple plasma ion source, the method comprising:extracting ions from a plasma chamber of an inductively coupled plasma ion source;forming an ion beam from the extracted ions;directing the ion beam toward the sample, the ion beam striking a plurality of apertures before making contact with the sample, wherein one or more apertures within the plurality of apertures has a material composition selected for low sputtering, the material composition comprising one or more of the following: carbon-based compounds, beryllium, vanadium, titanium, scandium, silicon, or niobium. 10. The method of claim 9 in which extracting ions from the plasma chamber comprises coupling a pulsed voltage waveform from a plasma igniter to the source biasing electrode to induce a high electric field at the lower end of the plasma chamber. 11. The method of claim 9 further comprising detecting the presence of a plasma within the ion source. 12. The method of claim 9 further comprising receiving a signal from a plasma sensor using electrically connected logic circuitry. 13. The method of claim 12 wherein the logic circuitry is configured to control the plasma igniter based on a signal from a plasma detector. 14. The method of claim 9, where in the focused ion beam system comprises a vacuum enclosure, wherein the vacuum enclosure contains the inductively coupled plasma ion source, and wherein the plasma igniter is mounted at or near the exterior of the vacuum enclosure. 15. The method of claim 9 wherein the inductively coupled plasma ion source comprises:an insulating plasma chamber;an RF antenna surrounding the plasma chamber;a match box electrically connected to the RF antenna;an RF power supply electrically connected to the match box; anda gas feed system configured to supply a feed gas for ionization into the plasma chamber. 16. The method of claim 9 wherein the plasma chamber comprises one or more of the following: ceramic, quartz, or machinable ceramic. 17. The method of claim 9, wherein the plurality of apertures comprises an aperture in a source biasing electrode, a beam acceptance aperture, and a beam defining aperture. 18. The method of claim 17, wherein the position of the beam acceptance aperture is controlled by a beam acceptance actuator and the position of the beam defining aperture is controlled by a beam defining actuator.