Add to ORKGAn optimized design of the main linac accelerating structure for a 500 GeV first stage of CLIC is presented. A similar long-range wakefield suppression scheme as for 3 TeV CLIC based on heavy waveguide damping is adopted. The accelerating gradient for the lower energy machine is 80 MV/m. The 500 GeV design has larger aperture radius in order to increase the maximum bunch charge and length which is limited by the short-range wakefields. The cell geometries have been optimized using a new parametric optimizer for Ace3P and details of the RF cell design are described. Field parameters for the full structure are calculated using a power flow equation
The main performance limits when designing acceler-ating structures for the Compact Linear Collider ...
The main performance limits when designing acceler-ating structures for the Compact Linear Collider ...
A novel procedure for the optimization of CLIC main linac parameters including operating frequency a...
We present a new optimized design of the accelerating structure for the main linac of CLIC (Compact ...
An alternative klystron-based scenario for the first stage of Compact Linear Collider (CLIC) at 380 ...
The Compact Linear Collider (CLIC) main linac uses waveguide damped structure as its baseline design...
The Compact Linear Collider (CLIC) main linac uses waveguide damped structure as its baseline design...
The present design of the main accelerating structure for CLIC is based on heavy damping (WDS) with ...
The Compact Linear Collider (CLIC) is a future e(+)e(−) linear collider. The CLIC study concentrated...
The baseline design of the Compact Linear Collider main linac accelerating structure is called ‘CLIC...
A new CLIC main-linac accelerating-structure design, HDS (Hybrid Damped Structure), with improved hi...
Abstract The design of the CLIC main linac accelerating structure has been refined based on an impro...
We report on the suppression of long-range wakefields in the main linacs of the CLIC collider. This ...
The rf design of an accelerating structure for the CLIC main linac is presented. The 12 GHz structur...
A new CLIC main‐linac accelerating‐structure design, HDS (Hybrid Damped Structure), with improved hi...
The main performance limits when designing acceler-ating structures for the Compact Linear Collider ...
The main performance limits when designing acceler-ating structures for the Compact Linear Collider ...
A novel procedure for the optimization of CLIC main linac parameters including operating frequency a...
We present a new optimized design of the accelerating structure for the main linac of CLIC (Compact ...
An alternative klystron-based scenario for the first stage of Compact Linear Collider (CLIC) at 380 ...
The Compact Linear Collider (CLIC) main linac uses waveguide damped structure as its baseline design...
The Compact Linear Collider (CLIC) main linac uses waveguide damped structure as its baseline design...
The present design of the main accelerating structure for CLIC is based on heavy damping (WDS) with ...
The Compact Linear Collider (CLIC) is a future e(+)e(−) linear collider. The CLIC study concentrated...
The baseline design of the Compact Linear Collider main linac accelerating structure is called ‘CLIC...
A new CLIC main-linac accelerating-structure design, HDS (Hybrid Damped Structure), with improved hi...
Abstract The design of the CLIC main linac accelerating structure has been refined based on an impro...
We report on the suppression of long-range wakefields in the main linacs of the CLIC collider. This ...
The rf design of an accelerating structure for the CLIC main linac is presented. The 12 GHz structur...
A new CLIC main‐linac accelerating‐structure design, HDS (Hybrid Damped Structure), with improved hi...
The main performance limits when designing acceler-ating structures for the Compact Linear Collider ...
The main performance limits when designing acceler-ating structures for the Compact Linear Collider ...
A novel procedure for the optimization of CLIC main linac parameters including operating frequency a...