PARALLEL FINITE ELEMENT MODELING TOOLS FOR ERL DESIGN AND ANALYSIS

1. Track3P Expt. MP bands Liling Xiao, Volkan Akcelik, Arno Candel, Lixin Ge, Andreas Kabel, Kwok Ko, Lie-Quan Lee, Zenghai Li, Cho Ng, Greg Schussman SLAC, Menlo Park, CA 94025, USA With support from SLAC’s accelerator program and the DOE SciDAC project, the Advanced Computations Department has developed a suite of 3D parallel finite element electromagnetic codes aimed at high-accuracy, high-fidelity simulations that can help address the design issues and analysis challenges in ERLs which include SRF gun design, cavity HOM damping, beam heating, and multipacting. PARALLEL FINITE ELEMENT MODELING TOOLS FOR ERL DESIGN AND ANALYSIS HOM Damping Evaluation with Omega3P (Eigensolver) SLAC Parallel Finite Element Codes TESLA TDR Cavity • Omega3P results based on an ideal • cavity (in black); • Measurements from 8 cavities in TTF • module 5 (in color), showing cavity • imperfections; • Cavity imperfection is studied to • identify critical dimensions affecting Qe. For accelerator modeling requiring • Complexity – Disparate length scales (unstructured mesh for model fidelity) • Problem size – Multiple cavities (large memory of supercomputers needed) • Accuracy – Resolve close mode spacing (higher order curved elements) • Speed – Fast turn around time to impact design (code scalability important) 0.5 mm gap . Beam Heating Study with T3P (Transients & wakefields) SRF Gun Simulation with Pic3P (Particle-in-Cell) • High current and short bunch will generate large amount of HOM heating; • Broadband power spectrum computed for realistic 3D structure and bunch • size to study the beamline absorber efficiency. BNL Polarized SRF Gun (Design by J. Kewisch) ½ cell, 350 MHz, 24.5 MV/m, 5 MeV, solenoid (18 Gauss), recessed GaAs cathode at T=70K inserted via choke joint, cathode spot size 6.5 mm, Q=3.2 nC, 0.4eV initial energy Mode Spectrum in 2-cavity Structure XFEL (DESY) ERL (Cornell) Multipacting Analysiswith Track3P Scattered self-fields as calculated with Pic3P - retardation and wakefields are included from first principles • SNS SRF cavity HOM coupler • RF heating observed at HOM coupler • 3D simulations showed MP barriers close to measurements Mesh model near cathode Pic3P shows fast convergence of transverse emittance (DOFs: field degrees of freedom) Bunch at gun exit, colored by energy * Work supported by the US DOE under contract DE-AC02-76SF00515. This research used resources of the National Energy Research Scientific Computing Center and the National Center for Computational Sciences at Oak Ridge National Laboratory, which are supported by the Office of science of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231 and DE-AC05-00OR22725, respectively.