论文信息 - New developments in WARP: Progress toward end-to-end simulation 1 1 Work performed under auspices of U.S. DoE by LLNL, NRL, and LBNL under contracts W-7405-ENG-48, DE-AI02-93ER40799, DE-AI02-94ER54232, and DE-AC03-765F00098. Proceedings of the 12th International Symposium on Heavy Ion Inertial Fusio

New developments in WARP: Progress toward end-to-end simulation 1 1 Work performed under auspices of U.S. DoE by LLNL, NRL, and LBNL under contracts W-7405-ENG-48, DE-AI02-93ER40799, DE-AI02-94ER54232, and DE-AC03-765F00098. Proceedings of the 12th International Symposium on Heavy Ion Inertial Fusio

Abstract The development of a high current, heavy-ion beam driver for inertial confinement fusion requires a detailed understanding of the behavior of the beam, including effects of the strong self-fields. The necessity of including the self-fields of the beam makes particle-in-cell (PIC) simulation techniques ideal, and for this reason, the multi-dimensional PIC/accelerator code WARP has been developed. WARP [1] has been used extensively to study the creation and propagation of ion beams both in experiments and for the understanding of basic beam physics. An overview of the structure of the code will be presented along with a discussion of features that make the code an effective tool in the understanding of space-charge dominated beam behavior. Much development has been done on WARP increasing its flexibility and generality. Major additions include a generalized field description, an efficient steady-state modeling technique, a transverse slice model with a bending algorithm, further improvement of the parallel processing version, and capabilities for linking to chamber transport codes. With these additions, the capability of modeling a large scale accelerator from end-to-end comes closer to reality.

[1] T. C. Sangster,et al. Numerical simulation of intense-beam experiments at LLNL and LBNL , 1998 .

[2] A. Bruce Langdon,et al. On enforcing Gauss' law in electromagnetic particle-in-cell codes , 1992 .

[3] D. Grote,et al. Simulation studies of transverse resonance effects in space-charge-dominated beams 1 Work performed under the auspices of the U.S. Department of Energy by LLNL and NRL under contracts W-7405-ENG-48, DE-AI05-92ER54177, and DE-AI05-83ER40112. 1 , 1998 .

[4] Yannis Manolopoulos,et al. The BASIS System: A Benchmarking Approach for Spatial Index Structures , 1999, Spatio-Temporal Database Management.

[5] D. Grote. Three dimensional simulations of space charge dominated heavy ion beams with applications to inertial fusion energy , 1994 .

[6] F. Deadrick,et al. 2 MV Injector as the Elise Front-End and as an Experimental Facility , 1996 .

[7] D. Grote,et al. Methods used in WARP3d, a three-dimensional PIC/accelerator code , 1997 .

[8] Alex Friedman,et al. Three-dimensional simulations of high-current beams in induction accelerators with WARP3d , 1996 .

[9] Alex Friedman,et al. Three-dimensional particle simulation of heavy-ion fusion beams , 1992 .

[10] J. Vay,et al. A three-dimensional electromagnetic particle-in-cell code to simulate heavy ion beam propagation in the reaction chamber , 1996 .

[11] D. Callahan. Chamber propagation physics for heavy ion fusion , 1996 .