Strong beam-beam effects at the interaction point of a high-energy linear collider such as CLIC lead to an emittance growth for the outgoing beams, as well as to the production of beamstrahlung photons and e+e- coherent pairs. We present a conceptual design of the post-collision line for the nominal CLIC machine at 3 TeV, which separates the various components of the outgoing beam thanks to a vertical magnetic chicane, before transporting them to their respective dump
The 1.5 TeV Compact Linear Collider (CLIC) beams, with a total power of 14MWper beam, are disrupted ...
The CLIC study aims at a multi-TeV, high luminosity e+e- linear collider design. Beam acceleration u...
Lower limits on the crossing angle at the interaction-point (IP) of the compact linear collider (CLI...
Strong beam-beam effects at the interaction point of a high-energy e+e − linear collider such as CLI...
Strong beam-beam effects at the interaction point of a high-energy e+e- linear collider such as the ...
Strong beam-beam effects at the interaction point of a high-energy e+ e- linear collider such as CLI...
The CLIC beam delivery system focuses 1.5 TeV electron and positron beams to a nanometre-sized cross...
The 1.5 TeV Compact Linear Collider (CLIC) beams, with a total power of 14 MW per beam, are disrupte...
The CLIC beam delivery system focuses 1.5~TeV electron and positron beams to a nanometre-sized cross...
The 1.5 TeV CLIC beams, with a total power of 14 MW per beam, are disrupted at the interaction point...
In future linear e+ e- colliders, the beam-beam interaction will strongly affect the experimental co...
As part of the Post-Collision Diagnostic Lattice task of the ILPS work-package of EuroTeV, we discus...
In order to achieve high luminosity, the Compact Linear Collider (CLIC) has to be operated in the hi...
The aim of the Compact Linear Collider (CLIC) study is to design a high-energy linear e+e- collider....
We review the present design for the CLIC beam delivery system as configured for 3 TeV and for 500 G...
The 1.5 TeV Compact Linear Collider (CLIC) beams, with a total power of 14MWper beam, are disrupted ...
The CLIC study aims at a multi-TeV, high luminosity e+e- linear collider design. Beam acceleration u...
Lower limits on the crossing angle at the interaction-point (IP) of the compact linear collider (CLI...
Strong beam-beam effects at the interaction point of a high-energy e+e − linear collider such as CLI...
Strong beam-beam effects at the interaction point of a high-energy e+e- linear collider such as the ...
Strong beam-beam effects at the interaction point of a high-energy e+ e- linear collider such as CLI...
The CLIC beam delivery system focuses 1.5 TeV electron and positron beams to a nanometre-sized cross...
The 1.5 TeV Compact Linear Collider (CLIC) beams, with a total power of 14 MW per beam, are disrupte...
The CLIC beam delivery system focuses 1.5~TeV electron and positron beams to a nanometre-sized cross...
The 1.5 TeV CLIC beams, with a total power of 14 MW per beam, are disrupted at the interaction point...
In future linear e+ e- colliders, the beam-beam interaction will strongly affect the experimental co...
As part of the Post-Collision Diagnostic Lattice task of the ILPS work-package of EuroTeV, we discus...
In order to achieve high luminosity, the Compact Linear Collider (CLIC) has to be operated in the hi...
The aim of the Compact Linear Collider (CLIC) study is to design a high-energy linear e+e- collider....
We review the present design for the CLIC beam delivery system as configured for 3 TeV and for 500 G...
The 1.5 TeV Compact Linear Collider (CLIC) beams, with a total power of 14MWper beam, are disrupted ...
The CLIC study aims at a multi-TeV, high luminosity e+e- linear collider design. Beam acceleration u...
Lower limits on the crossing angle at the interaction-point (IP) of the compact linear collider (CLI...