Add to ORKGIn this paper, we present an 800 MHz crab cavity conceptual design for the LHC upgrade. The cell shape is optimized for lower maximum peak surface fields as well as higher transverse R/Q. A compact coax-to-coax coupler scheme is proposed to damp the LOM/SOM modes. A two-stub antenna with a notch filter is used as the HOM coupler to damp the HOM modes in the horizontal plane and rejects the operating mode at 800MHz. Multipacting (MP) simulations show that there are strong MP particles at the disks. Adding grooves along the short axis without changing the operating mode's RF characteristics can suppress the MP activities. Possible input coupler configurations are discussed
The LHC luminosity upgrade will involve the installation of thirty-two 400 MHz SRF crab cavities. Th...
Schemes utilizing crab cavities to achieve head-on beam-beam collisions were proposed for the LHC Hi...
The proposed LHC high luminosity upgrade requires two crabbing systems in increasing the peak lumino...
In this paper, we present a 800MHz crab cavity conceptual design for LHC upgrade, includin...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
The LHC is planning to employ crab cavities for the high luminosity upgrade. Old Dominion University...
A slim highly eccentric elliptical Crab cavity with vertical deflection at 800 MHz, compatible to be...
In 2017 the LHC is envisioned to increase its luminosity via an upgrade. This upgrade is likely to r...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
Crab cavities are proposed for the LHC upgrade to improve the luminosity. There are two possible cra...
A slim highly eccentric elliptical Crab cavity with vertical deflection at 800 MHz, compatible to be...
The FNAL 9-cell 3.9 GHz deflecting cavity designed for the CKM experiment was chosen as the baseline...
A compact 400 MHz SRF crab cavity is designed for LHC. The design has low surface fields, has no har...
The LHC luminosity upgrade will involve the installation of thirty-two 400 MHz SRF crab cavities. Th...
Schemes utilizing crab cavities to achieve head-on beam-beam collisions were proposed for the LHC Hi...
The proposed LHC high luminosity upgrade requires two crabbing systems in increasing the peak lumino...
In this paper, we present a 800MHz crab cavity conceptual design for LHC upgrade, includin...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
The LHC is planning to employ crab cavities for the high luminosity upgrade. Old Dominion University...
A slim highly eccentric elliptical Crab cavity with vertical deflection at 800 MHz, compatible to be...
In 2017 the LHC is envisioned to increase its luminosity via an upgrade. This upgrade is likely to r...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
Crab cavities are adapted as the baseline design for the LHC HiLumi upgrade to achieve head-on beam-...
Crab cavities are proposed for the LHC upgrade to improve the luminosity. There are two possible cra...
A slim highly eccentric elliptical Crab cavity with vertical deflection at 800 MHz, compatible to be...
The FNAL 9-cell 3.9 GHz deflecting cavity designed for the CKM experiment was chosen as the baseline...
A compact 400 MHz SRF crab cavity is designed for LHC. The design has low surface fields, has no har...
The LHC luminosity upgrade will involve the installation of thirty-two 400 MHz SRF crab cavities. Th...
Schemes utilizing crab cavities to achieve head-on beam-beam collisions were proposed for the LHC Hi...
The proposed LHC high luminosity upgrade requires two crabbing systems in increasing the peak lumino...