In the European framework “High Intensity Pulsed Proton Injector” (HIPPI), the 3D linac code comparison and benchmarking program with experiment have been initialed. PARMILA and HALODYN are involved in this work. Both of these codes have been developed and used for linac design and beam dynamics studies. In this paper, we compare the simulation results with experiment results which was carried out on the UNILAC Alvarez DTL. And discuss physics aspects of the different linac design and beam dynamics simulation codes
Two IH drift tube linacs (IH1 and IH2) will be part of the new high current injector of the GSI acce...
The UNIversal Linear ACcelerator (UNILAC) at GSI aims at provision of high brilliant heavy ion beams...
In linear accelerators, misalignments of the machine elements can cause considerable emittance growt...
The Spallation Neutron Source (SNS) project is a collaborative effort between Brookhaven, Argonne, ...
The GSI UNILAC, a heavy ion linac originally dedi-cated for low current beam operation, together wit...
A new beam-tracking code using a 3D electro-magnetic field map of a linac is being developed. In thi...
After an accelerator is operational, the simulation models, used in the design phase to study perfec...
The computer code PARMILA has been the primary tool for the design of proton and ion linacs in the U...
The computer code PARMILA has been the primary tool for the design of proton and ion linacs in the U...
For the low and middle energy of the High Intensity Proton Pulse Injector (HIPPI) a superconducting ...
The multi-particle code DYNAMION was developed for beam dynamics simulations of complex beam transpo...
In the framework of the GSI beam intensity upgrade pro-gram for the heavy ion synchrotron (SIS) the ...
The beam dynamics code DYNAC was benchmarked using the European Spallation Source (ESS) Proton Linac...
The antiproton physics program for future Facility for Antiproton and Ion Research (FAIR) at Darmsta...
Contributed paper - To be published in the proceedings of HB 2006, Tsukuba, Japan, May 29-June 2, 20...
Two IH drift tube linacs (IH1 and IH2) will be part of the new high current injector of the GSI acce...
The UNIversal Linear ACcelerator (UNILAC) at GSI aims at provision of high brilliant heavy ion beams...
In linear accelerators, misalignments of the machine elements can cause considerable emittance growt...
The Spallation Neutron Source (SNS) project is a collaborative effort between Brookhaven, Argonne, ...
The GSI UNILAC, a heavy ion linac originally dedi-cated for low current beam operation, together wit...
A new beam-tracking code using a 3D electro-magnetic field map of a linac is being developed. In thi...
After an accelerator is operational, the simulation models, used in the design phase to study perfec...
The computer code PARMILA has been the primary tool for the design of proton and ion linacs in the U...
The computer code PARMILA has been the primary tool for the design of proton and ion linacs in the U...
For the low and middle energy of the High Intensity Proton Pulse Injector (HIPPI) a superconducting ...
The multi-particle code DYNAMION was developed for beam dynamics simulations of complex beam transpo...
In the framework of the GSI beam intensity upgrade pro-gram for the heavy ion synchrotron (SIS) the ...
The beam dynamics code DYNAC was benchmarked using the European Spallation Source (ESS) Proton Linac...
The antiproton physics program for future Facility for Antiproton and Ion Research (FAIR) at Darmsta...
Contributed paper - To be published in the proceedings of HB 2006, Tsukuba, Japan, May 29-June 2, 20...
Two IH drift tube linacs (IH1 and IH2) will be part of the new high current injector of the GSI acce...
The UNIversal Linear ACcelerator (UNILAC) at GSI aims at provision of high brilliant heavy ion beams...
In linear accelerators, misalignments of the machine elements can cause considerable emittance growt...