In the paper, theoretical and numerical studies on temporal focusing of photoelectron bunch in time-dependent fields are continued. Presented are the results of computer modeling on electron-optical system with combined time-dependent electric and static magnetic fields to ensure both spatial focusing and temporal compressing of photoelectron bunch down to sub-femtosecond level. The peculiarity of space charge effect contribution to the bunch broadening in the case of time-dependent electric field is discussed.
In contrast to the conventional image intensifier with large work area, a streak image tube should possess additional important feature -the comparatively small temporal distortion at the entire work area of the photocathode. With this additional engineering restriction taken into account, a novel small-size meshless streak image tube has been developed by means of numerical optimization. The tube with 25-mm wide work area contains a pair of deflection plates to sweep the electron image along the 25 mm output phosphor screen that is separated by 100 mm from the photocathode. The electron image can be shuttered with a 300 V blanking electric pulse. Electron-optical magnification of the tube is unit; spatial resolution reaches 30 lp/mm over the entire photocathode work area; temporal resolution lies in the 20 -50 ps range, depending on the accelerating voltage (6 -15 kV).
Basing on perturbation technique, discussed are some urgent problems of computational charged particle optics including numerical evaluation of fringe fields and field perturbations caused by small deviation of the shape of electrodes from rotational or planar symmetry as well as aberrational analysis of charged particle beams in the most general tensor form.
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