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Assessment of applicability of cold plasma dispersion relation of slot region hiss based on Van Allen Probes observations

Zhu Qi Ma Xin Cao Xing Ni Bin-Bin Xiang Zheng Fu Song Gu Xu-Dong Zhang Yuan-Nong

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Assessment of applicability of cold plasma dispersion relation of slot region hiss based on Van Allen Probes observations

Zhu Qi, Ma Xin, Cao Xing, Ni Bin-Bin, Xiang Zheng, Fu Song, Gu Xu-Dong, Zhang Yuan-Nong
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  • Electron scattering caused by plasmapheric hiss is the dominant mechanism that is responsible for the formation of slot region (1.8 ≤ L ≤ 3) between the Earth’s inner and outer radiation belts. The cold plasma dispersion relation of plasmaspheric hiss is widely used to quantify its scattering effect on energetic electrons. However, the existence of hot plasmas in the realistic magnetospheric environment will modify the dispersion properties of plasmaspheric hiss. According to Van Allen Probes observations, we select all hiss events in the slot region and compare the observed hiss wave amplitudes with the converted hiss wave amplitudes deduced from cold plasma dispersion relation and electric field observations, and then study the dependence of the applicability of cold plasma dispersion relation of slot region hiss on spatial position and geomagnetic activity. The results show that the cold plasma approximation tends to overestimate the amplitude of slot region hiss. The difference between the observed amplitude and the converted hiss wave amplitude has a strong day night asymmetry. However, it shows a slight dependence on the level of geomagnetic activities. In addition, we find that the converted wave magnetic field intensity is significantly lower (higher) than the observed magnetic field intensity at lower frequencies (higher frequencies), which indicates that the cold plasma approximation generally overestimates (underestimates) the scattering effects of hiss waves on the lower (higher) energy electrons in the slot region. Our study confirms that the application scope of the cold plasma dispersion relation of slot hiss has strong spatial and frequency limitations, which is of great importance in deepening our understanding of the dynamic evolution of electrons in the slot region.
      Corresponding author: Cao Xing, cxing@whu.edu.cn ; Ni Bin-Bin, bbni@whu.edu.cn
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 42025404, 41904143, 41904144), the B-type Strategic Priority Program of the Chinese Academy of Sciences (Grant No. XDB41000000), and the China Postdoctoral Science Foundation (Grant Nos. 2020M672405, 2019M662700).
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  • 图 1  2015年5月23日范阿伦B观测到的嘶声波事件 (a)背景电子密度; (b) AE和Dst指数; (c)观测电场功率谱密度; (d)观测磁场功率谱密度; (e) 基于冷等离子理论的反演磁场功率谱密度; (f)传播角; (g)极化率; (h)平面度; (i)嘶声波观测(红色)和反演(蓝色)幅值. 图(c)—(e)中的品红线条对应下混杂频率fLHR

    Figure 1.  Overview of a plasmaspheric hiss event observed by Van Allen Probe B on 23 May 2015: (a) Ambient electron density; (b) AE index and SYM_H index; observed power spectral intensity of (c) electric field and (d) magnetic field; (e) converted power spectral intensity of magnetic field based on the cold plasma dispersion relation; (f) wave normal angle; (g) wave ellipticity; (h) wave planarity; (i) observed (red) and converted (blue) hiss wave amplitudes. The magenta lines in panels (c)–(e) correspond to the lower hybrid resonance frequency fLHR.

    图 2  嘶声波观测幅值与反演幅值比值(${\rm{log}}_{10}\left( {{B}_{\rm{obs}}}/{{B}_{\rm{cvt}}}\right)$)的(a)均值与(b)方差随L和MLT的全球二维统计分布; (c)—(f)比值的均值与方差在不同MLT区间随L-shell的一维统计分布; (g)—(j)在不同L-shell区间随MLT的一维统计分布

    Figure 2.  Global distribution of the (a) mean value and (b) variance of the ratio of observed hiss amplitudes and converted amplitudes (${\rm{log}}_{10}\left( {{B}_{\rm{obs}}}/{{B}_{\rm{cvt}}}\right)$) as a function of L-shell and MLT; (c)–(f) the mean value and variance of the ratio as a function of L-shell in different MLT sectors; (g)–(j) the mean value and variance of the ratio as a function of MLT in different L-shell ranges.

    图 3  不同地磁活动水平下, 嘶声波观测幅值与反演幅值比值(${\rm{log}}_{10}\left( {{B}_{\rm{obs}}}/{{B}_{\rm{cvt}}}\right)$)的均值和方差随L和MLT的全球统计分布(a)—(c)均值; (d)—(f)方差

    Figure 3.  From left to right, global distribution of the mean value and variance of the ratio of observed hiss amplitudes and converted amplitudes (${\rm{log}}_{10}\left( {{B}_{\rm obs}}/{{B}_{\rm cvt}}\right)$) as a function of L-shell and MLT, in different geomagnetic conditions: (a)–(c) mean value; (d)–(f) variance of the ratio.

    图 4  嘶声波观测的磁场功率谱密度与反演的磁场功率谱密度比值(${\rm{log}}_{10}\left( {{B}_{\rm{obs}}}/{{B}_{\rm{cvt}}}\right)$)的均值(蓝线)和方差(红线)随波动频率的变化

    Figure 4.  Mean value (blue) and variance (red) of the ratio of observed and converted power spectral intensity $( {\rm{log}}_{10}\left( {{B}_{\rm{obs}}}/{{B}_{\rm{cvt}}}\right)$) as a function of wave frequency.

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    Thorne R M, Smith E J, Burton R. K, Holzer R E 1973 J. Geophys. Res. Space Phys. 78 1581Google Scholar

    [2]

    Thorne R M, Church S R, Gorney D J 1979 J. Geophys. Res. Space Phys. 84 5241Google Scholar

    [3]

    Ni B, Li W, Thorne R M, Bortnik J, Ma Q, Chen L, Kletzing C A, Kurth W S, Hospodarsky G B, Reeves G D, Spence H E, Blake J B, Fennell J F, Claudepierre S G 2014 Geophys. Res. Lett. 41 1854Google Scholar

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    Shi R, Li W, Ma Q, Reeves G D, Kletzing C A, Kurth W S, Hospodarsky G B, Spence H E, Blake J B, Fennell J F, Claudepierre S G 2017 J. Geophys. Res. Space Phys. 122 10263Google Scholar

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    Su Z, Liu N, Zheng H, Wang Y, Wang S 2018 Geophys. Res. Lett. 45 565Google Scholar

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    Su Z, Liu N, Zheng H, Wang Y, Wang S 2018 Geophys. Res. Lett. 45 10921Google Scholar

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    Zhang W, Fu S, Gu X, Ni B, Xiang Z, Summers D, Zou Z, Cao X, Lou Y, Hua M 2018 Geophys. Res. Lett. 45 4618Google Scholar

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    Zhang W, Ni B, Huang H, Summers D, Fu S, Xiang Z, Gu X, Cao X, Lou Y, Hua M 2019 Geophys. Res. Lett. 46 5670Google Scholar

    [9]

    Smith E J, Frandsen A, Tsurutani B T, Thorne R M, Chan K W 1974 J. Geophys. Res. Space Phys. 79 2507Google Scholar

    [10]

    Meredith N P, Horne R B, Thorne Richard M, Summers D, Anderson R R 2004 J. Geophys. Res. Space Phys. 109 A06209Google Scholar

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    Santolík O, Parrot M, Storey L, Pickett J S, Gurnett D A 2001 Geophys. Res. Lett. 28 1127Google Scholar

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    Bortnik J, Thorne R M, Meredith N P 2008 Nature 452 62Google Scholar

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    Lyons L R, Thorne R M, Kennel C F 1972 J. Geophys. Res. Space Phys. 77 3455Google Scholar

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    Meredith N P, Horne R B, Glauert S A, Thorne R M, Summers D, Albert J M, Anderson R R 2006b J. Geophys. Res. Space Phys. 111 A05212Google Scholar

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    李柳元, 曹晋滨, 周国成 2008 地球物理学报 51 316Google Scholar

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    宗秋刚, 袁憧憬, 王永福, 苏振鹏 2013 中国科学: 地球科学 56 1118Google Scholar

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    王春琴, 张贤国, 沈国红, 张珅毅, 张效信, 黄聪, 李兴冀 2021 地球物理学报 64 1831Google Scholar

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    Zhao H, Ni B, Li X, Baker D N, Johnston W R, Zhang W, Xiang Z, Gu X, Jaynes A N, Kanekal S G, Blake J B, Claudepierre S G, Temerin M A, Funsten H O, Reeves G D, Boyd A J 2019 Nat. Phys. 15 367Google Scholar

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    Claudepierre S G, Ma Q, Bortnik J, O'Brien T P, Fennell J F, Blake J B 2020 Geophys. Res. Lett. 47 e2019GL086056Google Scholar

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    Kennel C F, Engelmann F 1966 Phys. Fluids 9 2377Google Scholar

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    Ma Q, Li W, Thorne R M, Nishimura Y, Zhang X J, Reeves G D, Kletzing C A, Kurth W S, Hospodarsky G B, Henderson M G, Spence H E, Baker D N, Blake J B, Fennell J F, Angelopoulos V 2016 J. Geophys. Res. Space Phys. 121 4217Google Scholar

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    Zhu Q, Cao X, Gu X, N i, B, Xiang Z, Fu S, Summers D, Hua M, Lou Y, Ma X, Guo Y, Guo D, Zhang W 2021 J. Geophys. Res. Space Phys. 126 A029057Google Scholar

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Metrics
  • Abstract views:  4668
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  • Cited By: 0
Publishing process
  • Received Date:  07 September 2021
  • Accepted Date:  11 October 2021
  • Available Online:  27 February 2022
  • Published Online:  05 March 2022

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