Final Report for "Design calculations for high-space-charge beam-to-RF conversion".
[摘要] Accelerator facility upgrades, new accelerator applications, and future design efforts are leading to novel klystron and IOT device concepts, including multiple beam, high-order mode operation, and new geometry configurations of old concepts. At the same time, a new simulation capability, based upon finite-difference âcut-cellâ boundaries, has emerged and is transforming the existing modeling and design capability with unparalleled realism, greater flexibility, and improved accuracy. This same new technology can also be brought to bear on a difficult-to-study aspect of the energy recovery linac (ERL), namely the accurate modeling of the exit beam, and design of the beam dump for optimum energy efficiency. We have developed new capability for design calculations and modeling of a broad class of devices which convert bunched beam kinetic energy to RF energy, including RF sources, as for example, klystrons, gyro-klystrons, IOT's, TWTâs, and other devices in which space-charge effects are important. Recent advances in geometry representation now permits very accurate representation of the curved metallic surfaces common to RF sources, resulting in unprecedented simulation accuracy. In the Phase I work, we evaluated and demonstrated the capabilities of the new geometry representation technology as applied to modeling and design of output cavity components of klystron, IOT's, and energy recovery srf cavities. We identified and prioritized which aspects of the design study process to pursue and improve in Phase II. The development and use of the new accurate geometry modeling technology on RF sources for DOE accelerators will help spark a new generational modeling and design capability, free from many of the constraints and inaccuracy associated with the previous generation of âstair-stepâ geometry modeling tools. This new capability is ultimately expected to impact all fields with high power RF sources, including DOE fusion research, communications, radar and other defense applications.
[发布日期] 2008-10-17 [发布机构]
[效力级别] [学科分类] 核物理和高能物理
[关键词] ACCELERATORS;ACCURACY;BEAM DUMPS;CAVITIES;COMMUNICATIONS;DESIGN;ENERGY EFFICIENCY;ENERGY RECOVERY;FLEXIBILITY;GEOMETRY;KINETIC ENERGY;KLYSTRONS;LINEAR ACCELERATORS;RADAR;SIMULATION;SPACE CHARGE Accelerators;Energy Recovering Linac;RF Sources;RF Devices;Klystron;IOT;Modeling;Design. [时效性]