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An initial study of a beam polarization system was made: a ''first look'' at the configuration, not an optimized design. The feasibility of a system in which the large spin rotation magnets are located outside the IR (interaction region) is discussed. The system can, in principle, be turned on or off to allow conventional operation of PEP or operation with the SRS (spin rotation system). Operation over a wide energy range also appears possible without moving magnets, with only a relatively small loss in longitudinal polarization. The IR is left unencumbered by the SRS, and the sources of synchrotron radiation are moved out of the IR. However, a careful study is necessary to determine the best design for reducing or eliminating this background radiation.

The cylindrically symmetric beam-foil collision produces excitation and alignment of atom and ion levels similar, but not identical, to that resulting at comparable energies from ion-atom or ion-molecule collisions. When the foil is tilted, the macroscopic change acts on the microscopic scale to produce coherent alignment and orientation of the excited levels. The maximum beam energy range bounding this interaction has not yet been defined. The dynamic interaction which produces these effects is currently not predicted by any theory, although the dynamics of the ions subsequent to the collision are well understood. Refinement of current experimental technique can be expected to better define the final foil surface. The beam-tilted-foil collision promises to be useful in the study of ionic structure via quantum beat, radio-frequency and level-crossing spectroscopy techniques, and may provide a useful probe for certain surface interactions. 4 figs, 48 refs.