Title :
CMAD: A new self-consistent parallel code to simulate the electron cloud build-up and instabilities
Author_Institution :
SLAC, Menlo Park
Abstract :
We present the features of CMAD, a newly developed self-consistent code which simulates both the electron cloud build-up and related beam instabilities. By means of parallel (Message Passing Interface - MPI) computation, the code tracks the beam in an existing (MAD-type) lattice and continuously resolves the interaction between the beam and the cloud at each element location, with different cloud distributions at each magnet location. The goal of CMAD is to simulate single- and coupled-bunch instability, allowing tune shift, dynamic aperture and frequency map analysis and the determination of the secondary electron yield instability threshold. The code is in its phase of development and benchmarking with existing codes. Preliminary results on benchmarking are presented in this paper.
Keywords :
application program interfaces; electron accelerators; electron beams; message passing; particle beam bunching; particle beam dynamics; physics computing; proton accelerators; proton beams; storage rings; CMAD; MPI computation; beam instabilities; coupled-bunch instability; dynamic aperture; electron cloud build-up; frequency map analysis; message passing interface; parallel computation; proton storage rings; secondary electron yield instability; self-consistent parallel code; Analytical models; Apertures; Cloud computing; Computational modeling; Computer interfaces; Concurrent computing; Distributed computing; Electron beams; Lattices; Message passing;
Conference_Titel :
Particle Accelerator Conference, 2007. PAC. IEEE
Conference_Location :
Albuquerque, NM
Print_ISBN :
978-1-4244-0916-7
DOI :
10.1109/PAC.2007.4440517
