Cleaning techniques for applied-b ion diodes

M. Cuneo, P. Menge, D. L. Hanson, W. E. Fowler, M. A. Bernard, G. Ziska, A. Filuk, James E. Bailey, M. Desjarlais, T. Lockner, T. J. Nash, D. Noack, S. Slutz, Dale Welch
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引用次数: 6

Abstract

Measurements and theoretical considerations indicate that the lithium-fluoride (LiF) lithium ion source operates by electron-assisted field-desorption, and provides a pure lithium beam for 10-20 ns. Evidence on both the SABRE (1 TW) and PBFA-II (20 TW) accelerators indicates that the lithium beam is replaced by a beam of protons, and carbon resulting from electron thermal desorption of hydrocarbon surface and bulk contamination with subsequent avalanche ionization. Appearance of contaminant ions in the beam is accompanied by rapid impedance collapse, possibly resulting from loss of magnetic insulation in the rapidly expanding and ionizing neutral layer. Electrode surface and source substrate cleaning techniques are being developed on the SABRE accelerator to reduce beam contamination, plasma formation, and impedance collapse. We have increased lithium current density a factor of 3 and lithium energy a factor of 5 through a combination of in-situ surface and substrate cleaning, impermeable substrate coatings, and field profile modifications.
应用离子二极管的清洗技术
测量和理论分析表明,氟化锂离子源通过电子辅助场解吸工作,并提供10-20 ns的纯锂束流。在SABRE (1 TW)和PBFA-II (20 TW)加速器上的证据表明,锂束被质子束取代,碳束是由碳氢化合物表面的电子热解吸和随后雪崩电离的大块污染产生的。污染离子在光束中的出现伴随着快速的阻抗崩溃,这可能是由于在快速膨胀和电离的中性层中失去磁绝缘造成的。电极表面和源基板清洁技术正在SABRE加速器上开发,以减少光束污染、等离子体形成和阻抗崩溃。通过现场表面和基材清洁、不渗透基材涂层和现场剖面修改,我们将锂电流密度提高了3倍,锂能量提高了5倍。
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