North west cape-induced electron precipitation and theoretical simulation

doi:10.1088/1674-1056/25/11/119401

中国物理B ›› 2016, Vol. 25 ›› Issue (11): 119401-119401.doi: 10.1088/1674-1056/25/11/119401

• GEOPHYSICS, ASTRONOMY, AND ASTROPHYSICS • 上一篇

North west cape-induced electron precipitation and theoretical simulation

Zhen-xia Zhang(张振霞), Xin-qiao Li(李新乔), Chen-Yu Wang(王辰宇), Lun-Jin Chen

1 National Earthquake Infrastructure Service, China Earthquake Administration, Beijing 100045, China;
2 Institute of High Energy Physics, Chinese Academic Sciences, Beijing 100049, China;
3 Peking University, Beijing 100871, China;
4 Department of Physics, University of Texas at Dallas, Richardson, Texas, USA

收稿日期:2016-04-16 修回日期:2016-07-27 出版日期:2016-11-05 发布日期:2016-11-05
通讯作者: Zhen-xia Zhang E-mail:zxzhang@neis.cn
基金资助:
Supported by the China Seismo-Electromagnetic Satellite Mission Ground-Based Verification Project of the Administration of Science, Technology, and Industry for National Defense and Asia-Pacific Space Cooperation Organization Project (APSCO-SP/PM-EARTHQUAKE).

North west cape-induced electron precipitation and theoretical simulation

Zhen-xia Zhang(张振霞)¹, Xin-qiao Li(李新乔)², Chen-Yu Wang(王辰宇)³, Lun-Jin Chen⁴

1 National Earthquake Infrastructure Service, China Earthquake Administration, Beijing 100045, China;
2 Institute of High Energy Physics, Chinese Academic Sciences, Beijing 100049, China;
3 Peking University, Beijing 100871, China;
4 Department of Physics, University of Texas at Dallas, Richardson, Texas, USA

Received:2016-04-16 Revised:2016-07-27 Online:2016-11-05 Published:2016-11-05
Contact: Zhen-xia Zhang E-mail:zxzhang@neis.cn
Supported by:
Supported by the China Seismo-Electromagnetic Satellite Mission Ground-Based Verification Project of the Administration of Science, Technology, and Industry for National Defense and Asia-Pacific Space Cooperation Organization Project (APSCO-SP/PM-EARTHQUAKE).

摘要/Abstract

摘要： Enhancement of the electron fluxes in the inner radiation belt, which is induced by the powerful North West Cape (NWC) very-low-frequency (VLF) transmitter, have been observed and analyzed by several research groups. However, all of the previous publications have focused on NWC-induced >100-keV electrons only, based on observations from the Detection of Electro-Magnetic Emissions Transmitted from Earthquake Regions (DEMETER) and the Geostationary Operational Environmental Satellite (GOES) satellites. Here, we present flux enhancements with 30-100-keV electrons related to NWC transmitter for the first time, which were observed by the GOES satellite at night. Similar to the 100-300-keV precipitated-electron behavior, the low energy 30-100-keV electron precipitation is primarily located east of the transmitter. However, the latter does not drift eastward to the same extent as the former, possibly because of the lower electron velocity. The 30-100-keV electrons are distributed in the L=1.8-2.1 L-shell range, in contrast to the 100-300-keV electrons which are at L=1.67-1.9. This is consistent with the perspective that the energy of the VLF-wave-induced electron flux enhancement decreases with higher L-shell values. We expand upon the rationality of the simultaneous enhancement of the 30-100- and 100-300-keV electron fluxes through comparison with the cyclotron resonance theory for the quasi-linear wave-particle interaction. In addition, we interpret the asymmetry characteristics of NWC electric power distribution in north and south hemisphere by ray tracing model. Finally, we present considerable discussion and show that good agreement exists between the observation of satellites and theory.

关键词: North West Cape electron precipitation, wave-particle interaction, quasi-linear diffusion equation, ray tracing

Abstract: Enhancement of the electron fluxes in the inner radiation belt, which is induced by the powerful North West Cape (NWC) very-low-frequency (VLF) transmitter, have been observed and analyzed by several research groups. However, all of the previous publications have focused on NWC-induced >100-keV electrons only, based on observations from the Detection of Electro-Magnetic Emissions Transmitted from Earthquake Regions (DEMETER) and the Geostationary Operational Environmental Satellite (GOES) satellites. Here, we present flux enhancements with 30-100-keV electrons related to NWC transmitter for the first time, which were observed by the GOES satellite at night. Similar to the 100-300-keV precipitated-electron behavior, the low energy 30-100-keV electron precipitation is primarily located east of the transmitter. However, the latter does not drift eastward to the same extent as the former, possibly because of the lower electron velocity. The 30-100-keV electrons are distributed in the L=1.8-2.1 L-shell range, in contrast to the 100-300-keV electrons which are at L=1.67-1.9. This is consistent with the perspective that the energy of the VLF-wave-induced electron flux enhancement decreases with higher L-shell values. We expand upon the rationality of the simultaneous enhancement of the 30-100- and 100-300-keV electron fluxes through comparison with the cyclotron resonance theory for the quasi-linear wave-particle interaction. In addition, we interpret the asymmetry characteristics of NWC electric power distribution in north and south hemisphere by ray tracing model. Finally, we present considerable discussion and show that good agreement exists between the observation of satellites and theory.

Key words: North West Cape electron precipitation, wave-particle interaction, quasi-linear diffusion equation, ray tracing

中图分类号: (Wave/particle interactions)

94.20.wj

94.30.Tz (Electromagnetic wave propagation) 93.85.Rt (Seismic methods)

张振霞, 李新乔, 王辰宇, Lun-Jin Chen. North west cape-induced electron precipitation and theoretical simulation[J]. 中国物理B, 2016, 25(11): 119401-119401.

Zhen-xia Zhang(张振霞), Xin-qiao Li(李新乔), Chen-Yu Wang(王辰宇), Lun-Jin Chen. North west cape-induced electron precipitation and theoretical simulation[J]. Chin. Phys. B, 2016, 25(11): 119401-119401.

参考文献 53

[1]	Reeves G D, Baker D N, Belian R D, Blake J B, Cayton T E, Fennell J F, Friedel R H W, Meier M M, Selesnick R S and Spence H E 1998 Geophys. Res. Lett. 25 3265
[2]	Li X, Baker D N, Temerin M, Cayton T E, Reeves E G D, Christensen R A, Blake J B, Looper M D, Nakamura R and Kannekal S G 1997 J. Geophy. Res. 102 14123
[3]	Su Z, Xiao F, Zheng H, He Z, Zhu H, Zhang M, Shen C, Wang Y, Wang S, Kletzing C, Kurth W, Hospodarsky G, Spence H, Reeves G, Funsten H, Blake J and Baker D 2014 Geophys. Res. Lett. 41 229
[4]	Horne R B, Thorne R M, Shiprits Y Y, Meredith N P, Glauert S A, Smith A J, Kanekal S G, Baker D N, Engebretson M J, Posch J L, Spasojevic M, Inan U S, Pickett J S and Decreau M E 2005 Nature 437 227
[5]	Su Z P, Xiao F L, Zheng H N and Wang S 2011 J. Geophys. Res. 116 A04205
[6]	Thorne R M, Ni B, Tao X and Horne R B 2010 Nature 467 943
[7]	Kimura, I, Matsumoto H, Mukai T, Hashimoto K, Bell T F, Inan U S, Helliwell R A and Katsufrakis J P 1983 J. Geophy. Res. 88 282
[8]	Imhof W L, Reagan J B, Voss H D, Gaines E E, Datlowe D W, Mobilia J, Helliwell R A, Inan U S, Katsufrakis J and Joiner R G 1983 Geophys. Res. Lett. 10 361
[9]	Inan U S, Chang H C and Helliwell R A 1985 J. Geophys. Res. 90 359
[10]	Inan U S, Golkowski M, Casey M K, Moore R C, Peter W, Kulkarni P, Kossey P, Kennedy E, Meth S and Smit P 2007 Geophys. R. L. 34 L02106
[11]	Graf K L, Inan U S, Piddyachiy D, Kulkarni P, Parrot M and Sauvaud J A 2009 J. Geophys. Res. 114 A07205
[12]	Parrot M, Benoist D, Berthelier J J, Blecki J, Chapuis Y, Colin F, Elie F, Fergeau P, Lagoutte D, Lefeuvre F, Legendre C, Lévêque M, Pincon J L, Poirier B, Seran H C and Zamora P 2006 Planet. Space Sci. 54 441
[13]	Sauvaud J A, Moreau T, Maggiolo R, Treilhou J P, Jacquey C, Cross A, Coutelier J, Rouzaud J, Penou E and Gangloff M 2006 Planet. Space Sci. 54 502
[14]	Sauvaud J A, Maggiolo R, Jacquey C, Parrot M, Berthelier J J, Gamble R J and Rodger C J 2008 Geophys. Res. Lett. 35 L09101
[15]	Li X Q, Ma Y Q, Wang P, Wang H Y, Lu H, Zhang X M, Huang J P, Shi F, Yu X X, Xu Y B, Meng X C, Wang H, Zhao X Y and Parrot M 2012 J. Geophys. Res. 117 A04201
[16]	Gamble R J, Rodger C J, Clilverd M A, Sauvaud J A, Thomson N R, Stewart S L, McCormick R J, Parrot M and Berthelier J J 2008 J. Geophys. Res. 113 A10211
[17]	Kernel C F and Petschek H E 1966 J. Geophys. Res. 71 1
[18]	Summers D 2005 J. Geophys. Res. 110 A08213
[19]	Starks M J, Quinn R A, Ginet G P, Albert J M, Sales G S, Reinisch B W and Song P 2008 J. Geophys. Res. 113 A09320
[20]	Schulz M and Lanzerotti L 1974 Particle Diffusion in the Radiation Belts, in Physics and Chemistry in Space 7 (New York:Springer-Verlag) p. 533
[21]	Tao X, Chan A A, Albert J M and Miller J A 2008 J. Geophys. Res. 113 A07212
[22]	Subbotin D A and Shprits Y Y 2009 Space Weather 7 S10001
[23]	Shprits Y Y, Chen L, Ukhorskiy A and Thorne R 2009 J. Geophys. Res. 114 A03219
[24]	Su Z, Zheng H and Wang S 2010 J. Geophys. Res. 115 A06203
[25]	Lenchek A, Singer S and Wentworth R 1961 J. Geophys. Res. 12 66 4027
[26]	Angerami J J and Thomas J O 1964 J. Geophys. Res. 69 4537
[27]	Inan U S, Chang H C and Helliwell R A 1984 J. Geophy. Res. 89 2891
[28]	in't Hout K J and Mishra C 2013 Appl. Numer. Math. 74 83
[29]	Lehtinen N G and Inan U S 2009 Geophys. Res. Lett. 36 L03104
[30]	Zhao S F, Zhang X M, Zhao Z Y, Shen X H and Zhou C 2015 Chin. J. Geophys. 58 2263(in Chinese)
[31]	Kennel C F 1969 Rev. Geophys. 7 379
[32]	Fälthammar C G 1965 J. Geophys. Res. 70 2503
[33]	Su Z, Zhu H, Xiao F, Zong Q, Zhou X, Zheng H, Wang Y, Wang S, Hao Y, Gao Z, He Z, Baker D, Spence H, Reeves G, Blake J and Wygant J 2015 Nat. Commun. 6 10096
[34]	Selesnick R S, Albert J M and Starks M J 2013 J. Geophys. Res. 118 628
[35]	Kennel C F and Engelmann F 1966 Phys. Fluids 9 2377
[36]	Bortnik J, Thorne R M and Inan U S 2008 Geophys. Res. Lett. 35 L21102
[37]	Inan U S, Bell T F and Helliwell R A 1978 J. Geophy. Res. 83 3235
[38]	Tao X and Bortnik J 2010 Nonlin. Processes Geophy. 17 599
[39]	Tao X, Bortnik J, Thorne R M, Albert J M and Li W 2012 Geophys. Res. Lett. 39 L06102
[40]	Tao X, Bortnik J, Albert J M, Thorne R M and Li W 2013 J. Atmospheric Solar-Terrestrial Phys. 99 67
[41]	Hikishima M, Yagitani S, Omura Y and Nagano I 2009 J. Geophy. Res. 114 A10205
[42]	Omura Y and Summers D 2006 J. Geophy. Res. 111 A09222
[43]	Su Z, Xiao F, Zheng H, Shen C, Wang Y and Wang S 2012 J. Geophy. Res. 117 A09222
[44]	Su Z, Zhu H, Xiao F, Zheng H, Shen C, Wang Y and Wang S 2013 J. Geophy. Res. 118 3188
[45]	Su Z, Zheng H and Wang S 2010 J. Geophy. Res. 115 A06203
[46]	Horne R B 1989 J. Geophy. Res. 94 8895
[47]	Chen L J, Bortnik J, Thorne R M, Horne R B and Jordanova V K 2009 Geophys. Res. Lett. 36 L22101
[48]	Chen L J, Thorne R M, Li W and Bortnik J 2013 J. Geophy. Res. 118 1074
[49]	Xiao F L, Chen L J, Zheng H N and Wang S 2007 J. Geophy. Res. 112 A10214
[50]	Zhang Z X, Li X Q, Wu S G, Ma Y Q, Shen X H, Chen H R, Wang P, You X Z and Yuan Y H 2012 Chin. J. Geophys. 55 1581(in Chinese)
[51]	Zhang Z X, Wang C Y, Shen X H, Li X Q and Wu S G 2014 Chin. Phys. B 23 109401
[52]	Zhang Z X, Wang C Y Li Q, Wu S G 2014 Acta Phys. Sin. 63 079401(in Chinese)
[53]	Wang P, Wang H Y, Ma Y Q, Li X Q, Lu H, Meng X C, Zhang J L, Wang H, Shi F, Xu Y B, Yu X X, Zhao X Y and Wu F 2011 Acta Phys. Sin. 60 039401(in Chinese)

North west cape-induced electron precipitation and theoretical simulation

North west cape-induced electron precipitation and theoretical simulation

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献 53

相关文章 10

Metrics

本文评价

推荐阅读 0

[1]	魏利, 孟伟东, 孙丽存, 曹新飞, 普小云. Measurement and verification of concentration-dependent diffusion coefficient: Ray tracing imagery of diffusion process[J]. 中国物理B, 2020, 29(8): 84206-084206.
[2]	朱霄龙, 王丰, 王正汹. Nonlinear simulation of multiple toroidal Alfvén eigenmodes in tokamak plasmas[J]. 中国物理B, 2020, 29(2): 25201-025201.
[3]	卫子安, 马锦秀, 弋开阳. Observation of double pseudowaves in an ion-beam-plasma system[J]. 中国物理B, 2018, 27(8): 85201-085201.
[4]	夏冬, 金铭, 白明. Asymmetrical mirror optimization for a 140 GHz TE_{22, 6} quasi-optical mode converter system[J]. 中国物理B, 2017, 26(7): 74101-074101.
[5]	张峰, 张宁宁, 张义, 闫森, 孙松, 鲍骏, 高琛. Theoretical simulation and analysis of large size BMP-LSC by 3D Monte Carlo ray tracing model[J]. 中国物理B, 2017, 26(5): 54201-054201.
[6]	常珊珊, 倪彬彬, 赵正予, 顾旭东, 周晨. Test particle simulations of resonant interactions between energetic electrons and discrete, multi-frequency artificial whistler waves in the plasmasphere[J]. 中国物理B, 2014, 23(8): 89401-089401.
[7]	张振霞, 王辰宇, 申旭辉, 李新乔, 吴书贵. Study of typical space wave-particle coupling eventspossibly related with seismic activity[J]. , 2014, 23(10): 109401-109401.
[8]	陈镇, 曹俊诚. Channel characterization at 120 GHz for future indoor communication systems[J]. 中国物理B, 2013, 22(5): 59201-059201.
[9]	吉飞宇, 杨春晓. Approximate derivative-dependent functional variable separation for quasi-linear diffusion equations with a weak source[J]. 中国物理B, 2013, 22(10): 100202-100202.
[10]	赵小峰, 黄思训, 盛峥. Ray tracing/correlation approach to estimation of surface-based duct parameters from radar clutter[J]. 中国物理B, 2010, 19(4): 49201-049201.