Add to ORKGCERN’s Compact linear collider (CLIC) will require crab cavities to align the bunches to provide effective head-on collisions. An X-band quasi-TM11 deflecting cavity has been designed and manufactured for testing at CERN’s Xbox-2 high power standalone test stand. The cavity is currently under test and has reached an input power level in excess of 40MW, with a measured breakdown rate of better than 10-5 breakdowns per pulse. This paper also describes surface field quantities which are important in assessing the expected BDR when designing high gradient structures
In order to extend the available range of data on achievable accelerating gradients and pulse length...
CLIC will require two crab cavities to align the beams to provide an effective head-on collision wit...
A normal-conducting, X-band traveling wave structure operating in the dipole mode has been systemati...
CERN’s Compact linear collider (CLIC) will require crab cavities to align the bunches to provide eff...
This thesis describes the development and operation of multiple high power X-band RF test facilities...
This thesis describes the development and operation of multiple high power X-band RF test facilities...
The compact linear collider (CLIC) requires a crab cavity to align bunches prior to collision. The b...
RF design of a crab cavity (2π/3, 11.9942 GHz) for the Compact Linear Collide (CLIC) is presented. A...
A crab cavity is required in the CLIC to allow effective head-on collision of bunches at the IP. A h...
The bunch size and crossing angle planned for CERN's compact linear collider CLIC dictate that crab ...
The CLIC machine incorporates a 20 mrad crossing angle at the IP to aid the extraction of spent beam...
The Compact Linear Collider (CLIC) is a proposed electron positron linear collider design aiming to ...
The CLIC machine incorporates a 20 mrad crossing angle at the IP to aid the extraction of spent beam...
Crab crossing is essential for high-luminosity colliders. The high-luminosity Large Hadron Collider ...
The compact linear collider (CLIC) requires a crab cavity to align bunches prior to collision. The b...
In order to extend the available range of data on achievable accelerating gradients and pulse length...
CLIC will require two crab cavities to align the beams to provide an effective head-on collision wit...
A normal-conducting, X-band traveling wave structure operating in the dipole mode has been systemati...
CERN’s Compact linear collider (CLIC) will require crab cavities to align the bunches to provide eff...
This thesis describes the development and operation of multiple high power X-band RF test facilities...
This thesis describes the development and operation of multiple high power X-band RF test facilities...
The compact linear collider (CLIC) requires a crab cavity to align bunches prior to collision. The b...
RF design of a crab cavity (2π/3, 11.9942 GHz) for the Compact Linear Collide (CLIC) is presented. A...
A crab cavity is required in the CLIC to allow effective head-on collision of bunches at the IP. A h...
The bunch size and crossing angle planned for CERN's compact linear collider CLIC dictate that crab ...
The CLIC machine incorporates a 20 mrad crossing angle at the IP to aid the extraction of spent beam...
The Compact Linear Collider (CLIC) is a proposed electron positron linear collider design aiming to ...
The CLIC machine incorporates a 20 mrad crossing angle at the IP to aid the extraction of spent beam...
Crab crossing is essential for high-luminosity colliders. The high-luminosity Large Hadron Collider ...
The compact linear collider (CLIC) requires a crab cavity to align bunches prior to collision. The b...
In order to extend the available range of data on achievable accelerating gradients and pulse length...
CLIC will require two crab cavities to align the beams to provide an effective head-on collision wit...
A normal-conducting, X-band traveling wave structure operating in the dipole mode has been systemati...