Ion mirror and ion-optical lens for imaging

The invention claimed is: 1. An ion mirror comprising: an ion entrance electrode section at the ion entrance to the ion mirror; an energy focussing electrode section for reflecting ions back along a longitudinal axis towards said ion entrance; a spatial focussing electrode section arranged between the ion entrance electrode section and the energy focussing electrode section for spatially focussing the ions; one or more DC voltage supply configured to apply different DC voltages to the ion entrance electrode section, the spatial focussing electrode section and the energy focussing electrode section, and to apply a DC potential to the ion entrance electrode section that is intermediate the DC potential applied to the spatial focussing electrode section and the DC potential applied to the energy focussing electrode section; wherein at least one first transition electrode is arranged between said ion entrance electrode section and said spatial focussing electrode section, wherein said one or more DC voltage supply is configured to apply a DC potential to said at least one first transition electrode that is intermediate the DC potential applied to the ion entrance electrode section and the DC potential applied to the spatial focussing electrode section; and wherein at least one second transition electrode is arranged between said energy focussing electrode section and said spatial focussing electrode section, wherein said one or more DC voltage supply is configured to apply a DC potential to said at least one second transition electrode that is intermediate the DC potential applied to the spatial focussing electrode section and the DC potential applied to the ion entrance electrode section. 2. The ion mirror of claim 1 , wherein the DC voltage supply is configured to apply multiple different DC potentials to different electrodes of the energy focussing electrode section for reflecting ions back along the longitudinal axis towards said ion entrance; and wherein the DC voltage supply is configured to apply a DC potential to the ion entrance electrode section that is intermediate the DC potential applied to the spatial focussing electrode section and the lowest DC potential applied to the energy focussing electrode section. 3. The ion mirror of claim 1 , wherein the spatial focussing electrode section focuses ions in a dimension (Y-dimension) that is orthogonal to said longitudinal axis (X-dimension). 4. The ion mirror of claim 1 , wherein the energy focussing electrode section comprises at least two electrodes at different positions along the longitudinal axis, wherein the DC voltage supply is configured to apply a different potential to each of the at least two electrodes so as to provide an electric potential profile along the energy focussing electrode section for reflecting ions along the longitudinal axis towards said ion entrance. 5. The ion mirror of claim 1 , wherein said at least one first transition electrode comprises ≥m first transition electrodes arranged at different positions along the longitudinal axis, wherein m is selected from the group comprising: 2; 3; 4; 5; 6; 7; 8; 9; and 10. 6. The ion mirror of claim 5 , wherein the voltage supply is configured to apply a different DC potential to each of the m first transition electrodes so as to provide an electric potential profile that progressively increases in a direction along said longitudinal axis from the spatial focussing section to the ion entrance section. 7. The ion mirror of claim 1 , wherein said at least one second transition electrode comprises ≥n second transition electrodes arranged at different positions along the longitudinal axis, wherein n is selected from the group comprising: 2; 3; 4; 5; 6; 7; 8; 9; and 10. 8. The ion mirror of claim 7 , wherein the voltage supply is configured to apply a different DC potential to each of the n second transition electrodes so as to provide an electric potential profile that progressively increases in a direction along said longitudinal axis from the spatial focussing section to the energy focussing electrode section. 9. An ion mirror comprising: an ion entrance electrode section at the ion entrance to the ion mirror; an energy focussing electrode section for reflecting ions back along a longitudinal axis towards said ion entrance; a spatial focussing electrode section arranged between the ion entrance electrode section and the energy focussing electrode section for spatially focussing the ions; one or more DC voltage supply configured to apply different DC voltages to the ion entrance electrode section, the spatial focussing electrode section and the energy focussing electrode section, and to apply a DC potential to the spatial focussing electrode section that is intermediate the DC potential applied to the ion entrance electrode section and a DC potential applied to the energy focussing electrode section; and wherein at least one first transition electrode is arranged between said ion entrance electrode section and said spatial focussing electrode section, wherein said one or more DC voltage supply is configured to apply a DC potential to said at least one first transition electrode that is intermediate the DC potential applied to the ion entrance electrode section and the DC potential applied to the spatial focussing electrode section; and wherein at least one second transition electrode is arranged between said energy focussing electrode section and said spatial focussing electrode section, wherein said one or more DC voltage supply is configured to apply a DC potential to said at least one second transition electrode that is below the DC potential applied to the spatial focussing electrode section. 10. A mass spectrometer comprising an ion mirror as claimed in claim 1 ; or comprising two ion mirrors, each of the type claimed in claim 1 , wherein the spectrometer is configured such that, in use, ions are reflected between the two ion mirrors, wherein the spectrometer is a time of flight mass spectrometer. 11. A time of flight mass spectrometer comprising: a time of flight region for separating ions according to their mass to charge ratio; and an ion optical lens for spatially focussing ions arranged within the time of flight region, said lens comprising: an ion entrance electrode section and an ion exit electrode section at opposite ends of the lens, and a spatial focussing electrode section arranged between the ion entrance and ion exit electrode sections for spatially focussing ions passing through the lens; one or more DC voltage supply configured to apply DC voltages to the ion entrance electrode section, the spatial focussing electrode section and the ion exit electrode section; and to apply a DC potential to the spatial focussing electrode section that is either lower or greater than both the DC potential applied to the ion entrance electrode section and the DC potential applied to the ion exit electrode section; at least one first transition electrode arranged between said ion entrance electrode section and said spatial focussing electrode section, wherein said one or more DC voltage supply is configured to apply a DC potential to said at least one first transition electrode that is intermediate the DC potential applied to the ion entrance electrode section and the DC potential applied to the spatial focussing electrode section; and at least one second transition electrode arranged between said ion exit electrode section and said spatial focussing electrode section, wherein said one or more DC voltage supply is configured to apply a DC potential to said at least one second transition electrode that is intermediate the DC potential applied to the ion exit electrode section an