用于激光干涉仪的低温目标输送--现状与未来挑战

IF 0.6 4区 物理与天体物理 Q4 PHYSICS, MULTIDISCIPLINARY
I. V. Aleksandrova, A. A. Akunets, E. R. Koresheva, A. I. Nikitenko, V. D. Zvorykin
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引用次数: 0

摘要

对于先进的惯性聚变能(IFE)激光设施而言,新的目标传送系统解决方案至关重要。列别杰夫物理研究所(LPI)提出了基于磁悬浮(MAGLEV)技术的原始目标传送概念。其运行原理是在梯度磁场中对第二类高温超导体(HTSC)进行量子悬浮。在此过程中,一个低温目标被放置在一个悬浮的 HTSC-sabot(机器人)内,该机器人在永磁导轨系统上方被加速。在本文中,我们将继续研究如何建造一个具有有限磁轨的回旋加速器,用于非接触式靶标输送。目标剑杆模型由第二代高温超导体(2G-HTSC)带制成,具有 J-PI-04-20Ag-20 铜结构和高涡流引脚,以确保加速过程的悬浮稳定性。经过仔细的演示实验(T ~ 80 K),HTSC-sabot 在加速过程中稳定地在圆形轨道上方运行。计算和实验结果在 T ~ 80 K 时非常吻合,因此可以估算出回旋加速器在工作温度 T ~ 17 K 时的运行性能。估算结果表明,对于磁场 В ~ 2 T,感应梯度 ∂B2/∂x ~ 2 × 102 T2/m,半径为 ~4 m 的回旋加速器可以在 a = 1000g 时克服目标注入速度 \({{{v}}_{{text\{inj}}}}}\) = 200 m/s,这是未来 IFE 电站的下限。对于现有的激光设备来说,在 a = 10-250g 的加速度范围内,可以轻松达到 20-100 m/s 的速度。此外,文章还从选择新型 HTSC 材料和改进 HTSC 沙盘设计的角度,讨论了 LPI 在回旋加速器加速领域大有可为的研究。所取得的成果为建造用于 IFE 的更高性能回旋加速器提供了设计参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Cryogenic Target Delivery for Laser IFE–Status and Future Challenges

Cryogenic Target Delivery for Laser IFE–Status and Future Challenges

New solutions for target delivery systems are essential for advanced inertial fusion energy (IFE) laser facilities. Original target delivery concept based on magnetic levitation (MAGLEV) technology has been proposed at the Lebedev Physical Institute (LPI). The operational principle is the quantum levitation of Type-II, high-temperature superconductors (HTSC) in gradient magnetic fields. In doing so, a cryogenic target is placed inside a levitating HTSC-sabot, which is accelerated above a permanent magnet guideway system. In this paper, we continue our researches on building a cyclotron accelerator with a limited magnetic track for noncontact target delivery. The target sabot models were made from second-generation high-temperature superconductor (2G-HTSC) tapes with a J-PI-04-20Ag-20 Cu structure and high vortex pinning to ensure levitation stability of the acceleration process. Careful execution of demo experiments (T ~ 80 K) clarify that the HTSC-sabot runs stably above the circular track during its acceleration. The calculation and experimental results are in a good agreement at T ~ 80 K, which allows estimating the running performance of the cyclotron accelerator at operating temperature T ~ 17 K. The estimations have shown that for magnetic fields В ~ 2 T with induction gradients ∂B2/∂x ~ 2 × 102 T2/m, the cyclotron accelerator with a radius of ~4 m can overcome the target injection velocity \({{{v}}_{{{\text{inj}}}}}\) = 200 m/s at a = 1000g, which is the lower limit for future IFE power plant. For existing laser facilities the velocities 20‒100 m/s can be easily reached for a more comfortable acceleration range a = 10‒250g. In addition, the article discusses promising research at the LPI in the field of cyclotron acceleration, both from the point of view of selecting new HTSC materials and improving the design of HTSC-sabots. The obtained results provide the design reference for building the higher-performance cyclotron accelerators for IFE.

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来源期刊
Bulletin of the Lebedev Physics Institute
Bulletin of the Lebedev Physics Institute PHYSICS, MULTIDISCIPLINARY-
CiteScore
0.70
自引率
25.00%
发文量
41
审稿时长
6-12 weeks
期刊介绍: Bulletin of the Lebedev Physics Institute is an international peer reviewed journal that publishes results of new original experimental and theoretical studies on all topics of physics: theoretical physics; atomic and molecular physics; nuclear physics; optics; lasers; condensed matter; physics of solids; biophysics, and others.
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