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FACET uses an instrument called a notch collimator, installed in the SLAC linac's Sector 20 bunch compressor, to split each of the linac's single electron bunches into two. The notch collimator takes advantage of the distribution of different energies of the incoming electrons to separate them into a leading "drive" bunch and following "witness" bunch. The drive bunch will knock electrons to the side as it passes through plasma inside the beam tube. The witness bunch will ride the electron wake created as the displaced plasma electrons spring back into place just behind it.
As they enter the notch collimator, the bunch of electrons—or later, positrons—necessarily has a distribution of energies that are highly correlated with position along the bunch. In the middle of the magnetic bunch compressor, the beam is dispersed in energy and in time. Thus, "collimating" a different portion of the bunch based on position will collimate a different portion of the bunch in time, and lead to different schemes for acceleration and bunch shapes. By placing a collimator of appropriate, variable geometry at different locations along the bunch, a wide variety of drive/witness bunch configurations can be created. One example that produces two bunches with a charge ratio, spacing and bunch length similar to that envisioned for a plasma wakefield linear collider is shown above. This technique can be used to generate an electron drive bunch with an electron witness bunch or a positron drive bunch along with a positron witness bunch.
The notch collimator produces two bunches of
electrons or two bunches of positrons. What about one positron and one
Currently, the linac can only deliver either
electrons or positrons to FACET because the sector 20 bunch compressor
only has one path and so can only be set up for one type of lepton.
However, the proposed sailboat chicane will
take the existing Sector 20 chicane and add another path allowing both
electrons and positrons to get through the final bunch compression.
A schematic view of the magnet layout is
shown above. The lower chicane already exists in sector 20 (this is the
third phase of the bunch compression). All initial experiments can be
carried out with this single line. At a later date the upper chicane
will be added to allow both electron and positron bunches to be placed
one behind the other, to allow a drive bunch and witness bunch
arrangement. The optics are arranged so that both bunches are compressed
and focused the same way at the final focus point.
The scheme for both bunches entails a
small-charged positron bunch accelerated ahead of a larger electron
bunch in the linac. The electron bunch is sent through the lower chicane
and the positrons through the upper chicane. Since the path lengths are
carefully made to be different, the positron bunch comes out just
behind the electron bunch at a position to be accelerated by the
electron plasma wake fields. The distance of the positrons behind the
electron bunch can be adjusted by slight adjustments of the length of
the upper chicane.
SLAC National Accelerator Laboratory, Menlo Park, CA
Operated by Stanford University for the U.S. Dept. of Energy