Ultra-compact plasma spectrometer

Therefore, at least the following is claimed: 1. An ultra-compact plasma spectrometer, comprising: a collimator assembly; an energy analyzer array that receives charged particles from the collimator at a first side of the energy analyzer, the energy analyzer array comprising a plurality of analyzer plates having distinct energy channels, where individual energy channels of the distinct energy channels comprise a plurality of parallel curved conducting plates extending across one of the plurality of analyzer plates from the first side of the energy analyzer to a second side of the energy analyzer that is opposite the first side; and a detector plate that detects charged particles exiting the second side of the energy analyzer array. 2. The ultra-compact plasma spectrometer of claim 1 , wherein the plurality of analyzer plates are stacked. 3. The ultra-compact plasma spectrometer of claim 2 , wherein individual ones of the plurality of analyzer plates include a plurality of distinct energy channels. 4. The ultra-compact plasma spectrometer of claim 1 , wherein the distinct energy channels comprise nine parallel curved conducting plates. 5. The ultra-compact plasma spectrometer of claim 1 , wherein individual conducting plates of the plurality of parallel curved conducting plates have a thickness of 60 μm or less and are spaced apart by 80 μm or less. 6. The ultra-compact plasma spectrometer of claim 1 , wherein the plurality of parallel curved conducting plates have a curve radius to plate spacing ratio (R 1 /Δr) of 3,750. 7. The ultra-compact plasma spectrometer of claim 1 , wherein the energy analyzer array comprises a stack of 25 analyzer plates, each analyzer plate comprising eight energy channels. 8. The ultra-compact plasma spectrometer of claim 1 , wherein the collimator assembly comprises a plurality of wafers having aligned arrays of apertures. 9. The ultra-compact plasma spectrometer of claim 8 , wherein the plurality of wafers comprise single crystal silicon wafers. 10. The ultra-compact plasma spectrometer of claim 8 , wherein the apertures comprise an entrance opening that is substantially rectangular with a dimension of about 50 μm×50 μm or less. 11. The ultra-compact plasma spectrometer of claim 1 , wherein the detector plate comprises an array of silicon solid state detectors (SSSDs). 12. The ultra-compact plasma spectrometer of claim 11 , wherein the array of SSSDs detects ions with an energy level of 5 keV or less. 13. The ultra-compact plasma spectrometer of claim 1 , further comprising a power supply that energizes the distinct energy channels of the plurality of analyzer plates. 14. The ultra-compact plasma spectrometer of claim 13 , wherein the distinct energy channels of one of the plurality of analyzer plates is energized at different voltage levels. 15. The ultra-compact plasma spectrometer of claim 1 , wherein individual plates of the plurality of analyzer plates comprises a conductive layer disposed on an insulating layer, where the distinct energy channels are formed in the conductive layer. 16. A method, comprising: bonding a stack of analyzer plates to form an energy analyzer array, where individual analyzer plates comprise a plurality of energy analyzer bands extending from an entrance surface to an exit surface of the energy analyzer array; affixing a collimator assembly to the entrance surface of the energy analyzer array, the collimator assembly comprising a plurality of aperture arrays configured to align with the plurality of energy analyzer bands; and affixing an array of detectors to the exit surface of the energy analyzer array, the array of detectors aligned with the plurality of energy analyzer bands. 17. The method of claim 16 , comprising forming the plurality of energy analyzer bands in the individual analyzer plates, individual energy analyzer comprising a plurality of channels defined by one or more curved conducting plates and a pair of electrodes. 18. The method of claim 17 , comprising: bonding a conductive wafer to an insulating wafer, the insulating wafer comprising an insulating layer disposed on a surface adjacent to the conductive wafer; and etching the plurality of channels in the conductive wafer to form the energy analyzer bands in the individual analyzer plates. 19. The method of claim 16 , comprising etching apertures through a collimator wafer to form the plurality of aperture arrays. 20. The method of claim 19 , comprising bonding the collimator wafer to a second collimator wafer to form the collimator assembly, where apertures of the plurality of aperture arrays of the collimator wafer are substantially aligned with apertures of a plurality of aperture arrays of the second collimator wafer.