LMF消色差电磁聚焦系统的PIC仿真

Proceedings of the 1989 IEEE Particle Accelerator Conference, . 'Accelerator Science and Technology Pub Date : 1989-03-20 DOI:10.1109/PAC.1989.73338

T. Mehlhorn, J. Quintenz

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引用次数: 2

摘要

实验室微聚变设施(LMF)小球的标称1000兆焦耳当量至少需要1.5米半径的靶室来容纳爆炸。已经确定了一种几何形状，使用带有中心塞的环形离子束，总传输长度为4米，并且不允许从目标爆炸到离子二极管的直接视线。一个分析模型的消色差，双透镜系统，能够传输一个30毫瓦，1毫安的锂离子束在这个距离已经开发。该系统同时使用自b /次θ /和螺线管磁透镜。通过将最后的螺线管透镜定位在目标腔室壁上，使光束微发散要求最小化。在本工作中，用PIC(粒子在胞内)输运计算验证了分析模型。设计了一个实际的线圈系统，以提供所需的2-T螺线管场。模拟结果表明，如果在二极管处达到6 mrad的微散度，锂光束可以以超过70%的能量和功率效率传输4 m距离，向目标传输约1 MJ/束。

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PIC simulations of an achromatic solenoidal focusing system for LMF

The nominal 1000-MJ yield of a Laboratory Microfusion Facility (LMF) pellet requires at least a 1.5-m-radius target chamber to contain the blast. A geometry has been identified that uses an annular ion beam with a center plug, has a total transport length of 4 m, and allows no direct line of sight from the target blast to the ion diode. An analytic model for an achromatic, two-lens system that is capable of transporting a 30-MV, 1-MA Li ion beam over this distance has been developed. The system uses both self-B/sub theta / and solenoidal magnetic lenses. The beam microdivergence requirement is minimized by locating the final solenoidal lens at the target chamber wall. In the present work, the analytic model was verified by PIC (particle-in-cell) transport calculations. A realistic coil system has been designed to supply the required 2-T solenoidal fields. Simulations show that a lithium beam can be transported over the 4-m distance with better than 70% energy and power efficiency, delivering roughly 1 MJ/beam to the target if a 6-mrad microdivergence is achieved at the diode.<>

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来源期刊

Proceedings of the 1989 IEEE Particle Accelerator Conference, . 'Accelerator Science and Technology

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