A framework based on the YFS theorem enables process-independent local IR subtraction and resummation matching for automated NNLO_EW calculations in lepton collider processes.
CLICdp-Note-2018-002
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abstract
An updated luminosity staging baseline for CLIC is presented. Assuming accelerator ramp-up and up-time scenarios that are harmonized with those of other potential future colliders, CLIC will deliver 1 ab^-1 at sqrt(s)=380 GeV, 2.5 ab^-1 at sqrt(s)=1.5 TeV, and 5 ab^-1 at sqrt(s)=3 TeV. The complete programme will take 25-30 years. The baseline scenario for luminosity sharing between the two electron beam polarisation states is also discussed. Updated Higgs coupling sensitivities are given for this new luminosity staging baseline.
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CLIC could place 95% CL upper limits of 10^{-4} to 10^{-5} on the branching fractions of h→eμ, h→τμ, and h→eτ with 4 ab^{-1} at 1.4 TeV and 5 ab^{-1} at 3 TeV.
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Towards a Fully Automated Differential $\text{NNLO}_\text{EW}$ Generator for Lepton Colliders
A framework based on the YFS theorem enables process-independent local IR subtraction and resummation matching for automated NNLO_EW calculations in lepton collider processes.
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Lepton Flavor Violating Higgs decays at the Compact Linear Collider
CLIC could place 95% CL upper limits of 10^{-4} to 10^{-5} on the branching fractions of h→eμ, h→τμ, and h→eτ with 4 ab^{-1} at 1.4 TeV and 5 ab^{-1} at 3 TeV.