| A comparison of some of the capabilities of the LHC and CLIC at the high-energy frontier. Note the instances where photon beams (g) and polarization (P) might be advantages for CLIC |
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| Examples of benchmark physics processes for CLIC | |
| Main-beam and main-linac parameters for CLIC at 3 TeV c.m. | |
| Transverse normalized-emittance estimated growths at different stages of acceleration, transfer and delivery | |
| Longitudinal phase-space parameters at different stages of compression and acceleration | |
| Injector basic parameters at different stages | |
| Positron source parameters for different linear collider studies | |
| Tentative collector and damping ring parameters | |
| Lattice-geometry parameters in each sector of the linac | |
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Single-bunch vertical emittance increase after various static corrections |
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| Multibunch vertical emittance after static correction and possible re-optimization | |
| Vertical emittance dilution due to uncontrollable time-dependent effects, which adds to the multibunch emittance increase remaining after static corrections | |
| Fundamental mode parameters of the TDS as calculated using HFSS | |
| Main parameters of a drive-beam unit | |
| Beam characteristics required at the injector exit | |
| Preliminary simulation results at the front-end exit | |
| Parameters of the first and last cell of the 937 MHz structure | |
| Six- and seven-beam MBK design parameters | |
| Baseline modulator parameters | |
| Delay line parameters | |
| Ring parameters | |
| Isochronous module parameters | |
| Parameters of the four-waveguide PETS | |
| Parameters of the six-waveguide PETS | |
| Component efficiencies (%) | |
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Proposed definition of component classes |
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| A consistent set of measured values from two 30 GHz modules in CTF2 | |
| Comparison of CTF3, CLIC1 and CLIC (3 TeV) parameters | |
| CLIC parameters associated with the main beam at various energies | |
| Parameters associated with the RF power source for the 3 TeV CLIC |