Interplanetary medium monitoring with LISA: lessons from LISA Pathfinder

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
A. Cesarini, C. Grimani, M. Fabi, Federico Sabbatini, M. Villani, S. Benella, D. Telloni
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引用次数: 2

Abstract

The Laser Interferometer Space Antenna (LISA) of the European Space Agency (ESA) will be the first low-frequency gravitational-wave observatory orbiting the Sun at 1 AU.  The LISA Pathfinder (LPF) mission, aiming at testing of the instruments to be located on board the LISA spacecraft (S/C), hosted, among the others, fluxgate magnetometers and a particle detector as parts of a diagnostics subsystem.  These instruments allowed us for the estimate of the magnetic and Coulomb spurious forces acting on the test masses that constitute the  mirrors of the interferometer.  With these instruments we also had the possibility to study the galactic cosmic-ray short term-term variations as a function of the particle energy and the associated interplanetary disturbances. Platform magnetometers and particle detectors will be also placed on board each LISA S/C. This work reports about an empirical method that allowed us to disentangle the interplanetary and onboard-generated components of the magnetic field by using the LPF magnetometer measurements. Moreover, we estimate the number and fluence of solar energetic particle events expected to be observed with the ESA Next Generation Radiation Monitor during the  mission lifetime. An additional cosmic-ray detector, similar to that designed for LPF, in combination with magnetometers, would permit to observe the evolution of recurrent and non-recurrent galactic cosmic-ray variations and associated increases of the interplanetary magnetic field at the transit of high-speed solar wind streams and interplanetary counterparts of coronal mass ejections.
利用LISA进行星际介质监测:从LISA Pathfinder获得的经验教训
欧洲空间局(ESA)的激光干涉仪空间天线(LISA)将是第一个低频引力波天文台,绕太阳运行1天文单位。LISA探路者(LPF)任务旨在测试LISA航天器(S/C)上的仪器,其中包括磁通门磁力计和粒子探测器,作为诊断子系统的一部分。这些仪器使我们能够估计作用在构成干涉仪镜面的测试质量上的磁力和库仑伪力。有了这些仪器,我们也有可能研究星系宇宙射线的短期变化,作为粒子能量的函数和相关的行星际扰动。平台磁力计和粒子探测器也将安装在每台LISA S/C上。这项工作报告了一种经验方法,使我们能够通过使用LPF磁力计测量来解开行星际和机载磁场产生的成分。此外,我们估计了欧空局下一代辐射监测仪在任务寿命期间预计观测到的太阳高能粒子事件的数量和影响。一个额外的宇宙射线探测器,类似于为LPF设计的探测器,与磁力计相结合,将允许观察周期性和非周期性星系宇宙射线变化的演变,以及在高速太阳风流和日冕物质抛射的行星际对应的行星际磁场的相关增加。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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