Quasi-planar multi-reflecting time-of-flight mass spectrometer

What is claimed is: 1. A multi-reflecting time-of-flight mass spectrometer comprising: two electrostatic ion mirrors extended along a drift Z-direction and formed of parallel electrodes, wherein said ion mirrors are separated by a field-free region, wherein said parallel electrodes of at least one of said ion mirrors comprises an auxiliary electrode, and wherein said auxiliary electrode comprises a plurality of mask windows spaced along the drift Z-direction of the auxiliary electrode, each of the plurality of mask windows has a Z-directional length and a Y-directional height, and wherein the Z-directional length is larger than the Y-directional height; a pulsed ion source to release ion packets into said field-free region at an angle to an X-direction which is orthogonal to the drift Z-direction, such that the ion packets are reflected between said ion mirrors and drift along the drift Z-direction; and a receiver to receive the ion packets; wherein said ion mirrors are positioned to provide time-of-flight focusing on said receiver and to provide spatial focusing in a Y-direction orthogonal to both the drift Z-direction and the X-direction. 2. The apparatus as defined in claim 1 , wherein at least one of said ion mirrors comprises at least four electrodes with at least one of said at least four electrodes having an attracting potential applied thereto to provide said time-of-flight focusing and said spatial focusing in the Y-direction. 3. A multi-reflecting time-of-flight mass spectrometer comprising: two electrostatic ion mirrors extended along a drift Z-direction and formed of parallel electrodes, wherein said ion mirrors are separated by a field-free region; a pulsed ion source to release ion packets into said field-free region at an angle to an X-direction which is orthogonal to the drift Z-direction, such that the ion packets are reflected between said ion mirrors and drift along the drift Z-direction; and a receiver to receive the ion packets, wherein said ion mirrors are positioned to provide time-of-flight focusing on said receiver and to provide spatial focusing in a Y-direction orthogonal to both the drift Z-direction and the X-direction, wherein at least one of said ion mirrors comprises a periodic feature providing modulation of electrostatic field along the drift Z-direction for the purpose of periodic spatial focusing of the ion packets in the drift Z-direction, wherein said periodic feature comprises an opening in at least one of said electrodes, and wherein said opening varies in height in the Y-direction. 4. A multi-reflecting time-of-flight mass spectrometer comprising: two electrostatic ion mirrors extended along a drift Z-direction and formed of parallel electrodes, wherein said ion mirrors are separated by a field-free region; a pulsed ion source to release ion packets into said field-free region at an angle to an X-direction which is orthogonal to the drift Z-direction, such that the ion packets are reflected between said ion mirrors and drift along the drift Z-direction; and a receiver to receive the ion packets, wherein said ion mirrors are positioned to provide time-of-flight focusing on said receiver and to provide spatial focusing in a Y-direction orthogonal to both the drift Z-direction and the X-direction, wherein at least one of said ion mirrors comprises a periodic feature providing modulation of electrostatic field along the drift Z-direction for the purpose of periodic spatial focusing of the ion packets in the drift Z-direction, and wherein said periodic feature comprises a varying width in the X-direction of at least one of said electrodes. 5. A multi-reflecting time-of-flight mass spectrometer comprising: two electrostatic ion mirrors extended along a drift Z-direction and formed of parallel electrodes, wherein said ion mirrors are separated by a field-free region; a pulsed ion source to release ion packets into said field-free region at an angle to an X-direction which is orthogonal to the drift Z-direction, such that the ion packets are reflected between said ion mirrors and drift along the drift Z-direction; and a receiver to receive the ion packets, wherein said ion mirrors are positioned to provide time-of-flight focusing on said receiver and to provide spatial focusing in a Y-direction orthogonal to both the drift Z-direction and the X-direction, wherein at least one of said ion mirrors comprises a periodic feature providing modulation of electrostatic field along the drift Z-direction for the purpose of periodic spatial focusing of the ion packets in the drift Z-direction, and wherein said periodic feature comprises a set of periodic lenses incorporated into at least one of said electrodes. 6. The apparatus as defined in claim 1 , wherein said ion mirrors each comprise an auxiliary electrode, and wherein a potential of the auxiliary electrodes varies periodically in the Z-direction. 7. The apparatus as defined in claim 1 , wherein said periodic feature has a period equal to integer number of trajectory periods of the ion packets. 8. The apparatus as defined in claim 1 , wherein each of said two electrostatic ion mirrors comprises a quasi-planar electrostatic ion mirror. 9. The apparatus as defined in claim 1 , wherein said periodic feature has a period equal to N*ΔZ/2, where N is an integer and ΔZ is an advance of the ion packets in the drift Z-direction per reflection. 10. The apparatus as defined in claim 5 , wherein said at least one of said electrodes comprises an internal electrode of said at least one of said mirrors, wherein said internal electrode resides at an X-directional edge of said at least one of said mirrors, and wherein said edge borders said field-free region. 11. A multi-reflecting time-of-flight mass spectrometer comprising: two planar or quasi-planar electrostatic ion mirrors, each of said ion mirrors comprising a plurality of parallel electrodes extended along a Z-direction and each of said ion mirrors forming an electrostatic field; a field-free region residing between said ion mirrors; a pulsed ion source; a receiver; and a periodic spatial modulation of at least one of said electrostatic fields of said ion mirrors in the Z-direction, wherein said pulsed ion source releases ion packets into said field-free region, wherein the ion packets travel through said field-free region along a jigsaw trajectory formed by said ion mirrors reflecting the ion packets in an X-direction and by a drift of the ion packets in the Z-direction, wherein the ion packets are received by said receiver upon conclusion of travel along the jigsaw trajectory, wherein said periodic spatial modulation Z-directionally focuses the ion packets, and wherein said periodic spatial modulation is achieved by periodic openings in at least one of said electrodes. 12. The apparatus as defined in claim 11 , wherein said at least one of said ion mirrors comprises two adjacent mirror electrodes and an auxiliary electrode residing between said two adjacent mirror electrodes, and wherein said periodic openings are formed into said auxiliary electrode. 13. The apparatus as defined in claim 12 , wherein said adjacent mirror electrodes each have an elongated opening, each of said elongated openings having a Y-directional opening height and extending Z-directionally at least partially across its corresponding said adjacent mirror electrode, and wherein said periodic openings each have a Y-directional height equal to said Y-directional opening height of said elongated openings. 14. The apparatus as defined in claim 12 , wherein a Z-directional spacing between said periodic openings is equal to an ion advance