卡西尼等离子体光谱仪离子质谱仪在土星轨道插入期间观测到的土星F-G环间隙内的等离子体质子环境

IF 2.9 2区地球科学 Q2 ASTRONOMY & ASTROPHYSICS Journal of Geophysical Research: Space Physics Pub Date : 2025-02-06 DOI:10.1029/2023JA031614

E. C. Sittler Jr., A. K. Woodson, R. E. Johnson, J. F. Cooper, W.-L. Tseng, S. J. Sturner, D. J. Chornay, H. T. Smith, D. G. Simpson, D. B. Reisenfeld

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摘要

本文报道了基于卡西尼等离子体光谱仪（CAPS）离子质谱仪（IMS）飞行时间（TOF）组成测量数据在土星轨道插入（SOI）出站期间获得的土星F环和G环之间的质子检测和潜在的H2+检测。偶极子L壳层的范围为2.3 <；L & lt;2.8. E. C. Sittler等人（2017）提出了基于TOF数据的初步结果。下面是我们分析的最新结果。在F环和G环之间的SOI出站通道中，CAPS IMS处于加速后电压降低的模式，为- 6 kV，而不是通常的- 14.6 kV。与较重的离子O+和O2+相比，这种降低的电压仍然允许对质子进行分析，因为6 keV的质子被仪器的超薄碳箔散射的程度最低。我们的分析考虑了穿透辐射的背景噪声和仪器内部O+离子箔散射产生的鬼峰。通过假设质子速度分布函数为麦克斯韦方程组，分析可以确定质子密度、温度和流速，并计算出航天器的势能。在航天器参考系中，平均质子密度nP = 3.4±1.2 #/cm3，质子温度TP = 1.74±0.12 eV，质子同步流速度VP = 24±1.5 km/s，航天器电位ΦSC =−0.8±1.5 V。这些结果与先前对土星内磁层中氢离子和氢离子的理论估计进行了比较。

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The Plasma Proton Environment Within Saturn's F-G Ring Gap as Observed by the Cassini Plasma Spectrometer Ion Mass Spectrometer During Saturn Orbit Insertion

We report on the detection of protons and the potential detection of H₂⁺ between Saturn's F and G rings based on Cassini Plasma Spectrometer (CAPS) Ion Mass Spectrometer (IMS) time-of-flight (TOF) composition measurements acquired during Saturn Orbit Insertion (SOI) outbound pass. The range in dipole L shell is 2.3 < L < 2.8. Initial results based on TOF data were presented in E. C. Sittler et al. (2017). Here we present the latest results of our analysis. During the SOI outbound pass between the F and G rings the CAPS IMS was in a mode of reduced post-acceleration voltage at −6 kV instead of the usual −14.6 kV. This reduced voltage still allows the analysis of protons since 6 keV protons are minimally scattered by the instrument's ultrathin carbon foils when compared to heavier ions O⁺ and O₂⁺. Background noise from penetrating radiation and ghost peaks produced by foil-scattered O⁺ ions within the instrument were considered in our analysis. The analysis allowed an determination of the proton density, temperature and flow velocity, accounting for spacecraft potential by assuming a convected Maxwellian for the proton velocity distribution function. We find average proton density n_P = 3.4 ± 1.2 #/cm³, proton temperature T_P = 1.74 ± 0.12 eV, proton corotation flow speed V_P = 24 ± 1.5 km/s in spacecraft reference frame and spacecraft potential Φ_SC = −0.8 ± 1.5 V. These results are compared with previous theoretical estimates of H⁺ and H₂⁺ ions within Saturn's inner magnetosphere.