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Download - Update on design of final TALs in the CLIC Drive Beam

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Page 1: Update on design of final TALs in the CLIC Drive Beam

Update on design of final TALs in the CLIC Drive Beam

R. Apsimon, J. Esberg

Page 2: Update on design of final TALs in the CLIC Drive Beam

Optimisation techniques

• Local optimisation– Each cell optimised separately• Easy to tune• Poor energy acceptance

– Sextupoles don’t help a lot

• Global optimisation– Match all sextupoles and quadrupoles• Very good energy acceptance• Very weak sextupoles needed

Page 3: Update on design of final TALs in the CLIC Drive Beam

• 20 sextupoles used– 4 sextupoles per arc cell– Maximum pole-tip field ~0.018 T

Page 4: Update on design of final TALs in the CLIC Drive Beam

Locally optimised solution

Page 5: Update on design of final TALs in the CLIC Drive Beam

Globally optimised solution

Page 6: Update on design of final TALs in the CLIC Drive Beam

Dispersion energy dependence

Page 7: Update on design of final TALs in the CLIC Drive Beam

R56 energy dependence

Page 8: Update on design of final TALs in the CLIC Drive Beam

Emittance growth vs sextupole strength: PLACET tracking

Page 9: Update on design of final TALs in the CLIC Drive Beam

Emittance growth vs sextupole strength: PLACET tracking

Page 10: Update on design of final TALs in the CLIC Drive Beam

Emittance growth vs sextupole strength: PLACET tracking

Page 11: Update on design of final TALs in the CLIC Drive Beam

Emittance growth vs sextupole strength: MADX-PTC tracking

HorizontalVertical

Longitudinal

Page 12: Update on design of final TALs in the CLIC Drive Beam

PLACET tracking: longitudinal phase space: no synchrotron radiation

Page 13: Update on design of final TALs in the CLIC Drive Beam

Emittance growth vs sextupole strength: PLACET tracking

HorizontalVertical

Longitudinal

Page 14: Update on design of final TALs in the CLIC Drive Beam

PTC tracking emittance growth

Horizontal Vertical LongitudinalLocal optimisation 138 μm.Rad 2.2 μm.Rad 1.8 μm.GeV

Global optimisation 3.0 μm.Rad 2.0 μm.Rad -0.0012 μm.GeV

PLACET 0.67 s.f. 3.0 μm.Rad 0.85 μm.Rad 0.0 μm.GeV


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