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1. Seasonal and diurnal dynamics of radio noise for 8-20MHz poleward-oriented mid-latitude radars

Author

Berngardt, O. I., Maurice, J. -P. St., Ruohoniemi, J. M., and Marchaudon, A.

Subjects
Physics - Space Physics, Physics - Geophysics
Abstract

Based on ray tracing in a smooth ionosphere described by the IRI-2016 model we have infered the seasonal-diurnal dynamics of radio noise observed by four mid-latitude HF radars. In the calculations, noise is assumed to propagate from the radar dead zone boundary. Noise absorption along the ray path is simulated from the IRI-2016 electron density, and from the molecular nitrogen density and electron temperatures obtained from the NRLMSISE-00 model. Model results are compared with experimental radar data, and good agreement between the two is demonstrated. The model makes it possible to estimate the amount of absorption in D- and E- layers under average undisturbed conditions. This is important for the retrieval of long term variations in the electron density in the lower ionosphere. The model also makes it feasible to interpret vertical absorption in experimental data, thereby significantly expanding the capability of HF radars to monitor the lower ionosphere., Comment: 22 pages, 7 figures, submitted to Radio Science

Published
2021
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2. Global diagnostics of ionospheric absorption during X-ray solar flares based on 8-20MHz noise measured by over-the-horizon radars

Author

Berngardt, O. I., Ruohoniemi, J. M., St-Maurice, J. -P., Marchaudon, A., Kosch, M. J., Yukimatu, A. S., Nishitani, N., Shepherd, S. G., Marcucci, M. F., Hu, H., Nagatsuma, T., and Lester, M.

Subjects
Physics - Geophysics, Physics - Space Physics
Abstract

An analysis of noise attenuation during eighty solar flares between 2013 and 2017 was carried out at frequencies 8-20 MHz using thirty-four SuperDARN radars and the EKB ISTP SB RAS radar. The attenuation was determined on the basis of noise measurements performed by the radars during the intervals between transmitting periods. The location of the primary contributing ground sources of noise was found by consideration of the propagation paths of radar backscatter from the ground. The elevation angle for the ground echoes was determined through a new empirical model. It was used to determine the paths of the noise and the location of its source. The method was particularly well suited for daytime situations which had to be limited for the most part to only two crossings through the D region. Knowing the radio path was used to determine an equivalent vertical propagation attenuation factor. The change in the noise during solar flares was correlated with solar radiation lines measured by GOES/XRS, GOES/EUVS, SDO/AIA, SDO/EVE, SOHO/SEM and PROBA2/LYRA instruments. Radiation in the 1 to 8$\mathring{A}$ and and near 100$\mathring{A}$ are shown to be primarily responsible for the increase in the radionoise absorption, and by inference, for an increase in the D and E region density. The data are also shown to be consistent with a radar frequency dependence having a power law with an exponent of -1.6. This study shows that a new dataset can be made available to study D and E region., Comment: 30 pages, 5 figures, 2 tables. Submitted to Space Weather

Published
2018
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3. Observation of Quiet‐Time Mid‐Latitude Joule Heating and Comparisons With the TIEGCM Simulation.

Author

Day, E. K., Grocott, A., Walach, M.‐T., Wild, J. A., Lu, G., Ruohoniemi, J. M., and Coster, A. J.

Subjects
GENERAL circulation model, PARTICLE motion, UPPER atmosphere, SPACE environment, ENTHALPY
Abstract

Joule heating is a major energy sink in the solar wind‐magnetosphere‐ionosphere system and modeling it is key to understanding the impact of space weather on the neutral atmosphere. Ion drifts and neutral wind velocities are key parameters when modeling Joule heating, however there is limited validation of the modeled ion and neutral velocities at mid‐latitudes. We use the Blackstone Super Dual Auroral Radar Network radar and the Michigan North American Thermosphere Ionosphere Observing Network Fabry‐Perot interferometer to obtain the local nightside ion and neutral velocities at ∼40° geographic latitude during the nighttime of 16 July 2014. Despite being a geomagnetically quiet period, we observe significant sub‐auroral ion flows in excess of 200 ms−1. We calculate an enhancement to the local Joule heating rate due to these ion flows and find that the neutrals impart a significant increase or decrease to the total Joule heating rate of >75% depending on their direction. We compare our observations to outputs from the Thermosphere Ionosphere Electrodynamic General Circulation Model (TIEGCM). At such a low geomagnetic activity however, TIEGCM was not able to model significant sub‐auroral ion flows and any resulting Joule heating enhancements equivalent to our observations. We found that the neutral winds were the primary contributor to the Joule heating rates modeled by TIEGCM rather than the ions as suggested by our observations. Plain Language Summary: Charged particle motion in Earth's upper atmosphere creates heating called Joule heating which causes the atmosphere to expand, increasing drag for objects and satellites. Charged particle velocities are typically greater at high‐latitudes than mid and lower latitudes. At mid and lower latitudes, Earth's neutral atmosphere can move faster than the charged particles and produce Joule heating. We can use ground based instruments to observe this particle motion and estimate the Joule heating. Physical models can estimate the Joule heating for different space weather conditions. These physical models show good estimations of the high‐latitude Joule heating compared to estimations, however there is limited validation of their performance at mid‐latitudes. We use ground based instruments to estimate the Joule heating over mid‐latitude North America for one night and compare to outputs from a physics model called the Thermosphere Ionosphere Electrodynamic General Circulation Model (TIEGCM). Despite quiet driving conditions, we observe significant charged particle motion driving enhanced Joule heating rates. We find that TIEGCM was unable to model these strong charged particle motions nor any Joule heating enhancements equivalent to our observations. While the observed heating resulted from faster charged particle motion, the Joule heating rates in TIEGCM were produced by the greater neutral winds instead of ion drifts. Key Points: Observations from a Fabry‐Perot interferometer and Super Dual Auroral Radar Network radar were used to estimate quiet‐time mid‐latitude Joule heating rates during 16 July 2014The neutral winds accounted for between 24% and 43% of the total observed local Joule heating ratesJoule heating enhancements were observed approximately 8 times higher than modeled by the Thermosphere Ionosphere Electrodynamic General Circulation Model due to excitations in sub‐auroral ion motion [ABSTRACT FROM AUTHOR]

Published
2024
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4. Exploring the relationship between STEVE and SAID during three events observed by SuperDARN.

Author

Macho, E. P., Bristow, W., Gallardo-Lacourt, B., Shepherd, S. G., Ruohoniemi, J. M., Correia, E., Nishitani, Nozomu, and Miyashita, Yukinaga

Subjects
AURORAS, IONOSPHERE, MAGNETIC storms, RESEARCH personnel, CANADIAN history
Abstract

The phenomenon known as strong thermal emission velocity enhancement (STEVE) is a narrow optical structure that may extend longitudinally for thousands of kilometers. Initially observed by amateur photographers, it has recently garnered researchers' attention. STEVE has been associated with a rapid westward flow of ions in the ionosphere, known as subauroral ion drift (SAID). In this work, we investigate three occurrences of STEVE, using data from one of the Time History of Events and Macroscale Interactions during Substorms (THEMIS) ground-based all-sky imagers (ASIs) located at Pinawa, Manitoba, and from the Super Dual Auroral Radar Network (SuperDARN). This approach allows us to verify the correlation between STEVE and SAID, as well as analyze the temporal variation of SAID observed during STEVE events. Our results suggest that the SAID activity starts before the STEVE, and the magnitude of the westward flow decreases as the STEVE progresses toward the end of its optical manifestation. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Driving Influences of the Doppler Flash Observed by SuperDARN HF Radars in Response to Solar Flares

Author

Chakraborty, S., Qian, L., Baker, J. B. H., Ruohoniemi, J. M., Kuyeng, K., Mclnerney, J. M., Chakraborty, S., Qian, L., Baker, J. B. H., Ruohoniemi, J. M., Kuyeng, K., and Mclnerney, J. M.

Abstract

Sudden enhancement in high-frequency absorption is a well-known impact of solar flare-driven Short-Wave Fadeout (SWF). Less understood, is a perturbation of the radio wave frequency as it traverses the ionosphere in the early stages of SWF, also known as the Doppler flash. Investigations have suggested two possible sources that might contribute to it’s manifestation: first, enhancements of plasma density in the D-and lower E-regions; second, the lowering of the F-region reflection point. Our recent work investigated a solar flare event using first principles modeling and Super Dual Auroral Radar Network (SuperDARN) HF radar observations and found that change in the F-region refractive index is the primary driver of the Doppler flash. This study analyzes multiple solar flare events observed across different SuperDARN HF radars to determine how flare characteristics, properties of the traveling radio wave, and geophysical conditions impact the Doppler flash. In addition, we use incoherent scatter radar data and first-principles modeling to investigate physical mechanisms that drive the lowering of the F-region reflection points. We found, (a) on average, the change in E- and F-region refractive index is the primary driver of the Doppler flash, (b) solar zenith angle, ray’s elevation angle, operating frequency, and location of the solar flare on the solar disk can alter the ionospheric regions of maximum contribution to the Doppler flash, (c) increased ionospheric Hall and Pedersen conductance causes a reduction of the daytime eastward electric field, and consequently reduces the vertical ion-drift in the lower and middle latitude ionosphere, which results in lowering of the F-region ray reflection point.

Published
2022

14. Inverse Energy Dispersion of Energetic Ions Observed in the Magnetosheath

Author

Lee, S. H, Sibeck, D. G, Hwang, K.-J, Wang, Y, Silveira, M. V. D, Fok, M.-C, Mauk, B. H, Cohen, I. J, Ruohoniemi, J. M, Kitamura, N, Burch, J. L, Giles, B. L, Torbert, R. B, Russell, C. T, and Lester, M

Subjects
Space Sciences (General)
Abstract

We present a case study of energetic ions observed by the Energetic Particle Detector (EPD) on the Magnetospheric Multiscale spacecraft in the magnetosheath just outside the subsolar magnetopause that occurred at 1000 UT on 8 December 2015. As the magnetopause receded inward, the EPD observed a burst of energetic (approximately 50-1000 keV) proton, helium, and oxygen ions that exhibited an inverse dispersion, with the lowest energy ions appearing first. The prolonged interval of fast antisunward flow observed in the magnetosheath and transient increases in the H components of global ground magnetograms demonstrate that the burst appeared at a time when the magnetosphere was rapidly compressed. We attribute the inverse energy dispersion to the leakage along reconnected magnetic field lines of betatron-accelerated energetic ions in the magnetosheath, and a burst of reconnection has an extent of about 1.5 R(sub E) using combined Super Dual Auroral Radar Network radar and EPD observations.

Published
2016
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22. Multi‐point Conjugate Observations of Dayside ULF Waves during an Extended Period of Radial IMF

Author

Shi, Xiaodong, Hartinger, M. D., Baker, J. B. H., Ruohoniemi, J. M., Lin, D., Xu, Z., Coyle, S., Kunduri, B. S. R., Kilcommons, L. M., Willer, A., Shi, Xiaodong, Hartinger, M. D., Baker, J. B. H., Ruohoniemi, J. M., Lin, D., Xu, Z., Coyle, S., Kunduri, B. S. R., Kilcommons, L. M., and Willer, A.

Abstract

Long‐lasting Pc5 ultralow frequency (ULF) waves spanning the dayside and extending from L ∼ 5.5 into the polar cap region were observed by conjugate ground magnetometers. Observations from MMS satellites in the magnetosphere and magnetometers on the ground confirmed that the ULF waves on closed field lines were due to fundamental toroidal standing Alfvén waves. Monochromatic waves at lower latitudes tended to maximize their power away from noon in both the morning and afternoon sectors, while more broadband waves at higher latitudes tended to have a wave power maximum near noon. The wave power distribution and MMS satellite observations during the magnetopause crossing indicate surface waves on a Kelvin‐Helmholtz (KH) unstable magnetopause coupled with standing Alfvén waves. The more turbulent ion foreshock during an extended period of radial interplanetary magnetic field (IMF) likely plays an important role in providing seed perturbations for the growth of the KH waves. These results indicate that the Pc5 waves observed on closed field lines and on the open field lines of the polar cap were from the same source.

Published
2020

23. Substorm-Associated Ionospheric Flow Fluctuations During the 27 March 2017 Magnetic Storm: SuperDARN-Arase Conjunction

Author

Shepherd, S. G., Ruohoniemi, J. M., Connors, M., Nakano, S., Kazama, Y., Wang, S. -Y., Tam, S. W. Y., Chang, T. -F., Wang, B. -J., Hori, Tomoaki, Nishitani, Nozomu, Teramoto, Mariko, Seki, Kanako, Takahashi, Naoko, Kasahara, Satoshi, Yokota, Shoichiro, Mitani, Takefumi, Takashima, Takeshi, Higashio, Nana, Matsuoka, Ayako, Asamura, Kazushi, Miyoshi, Yoshizumi, and Shinohara, Iku

Subjects
Geomagnetic storm, Physics, Geophysics, 010504 meteorology & atmospheric sciences, Flow (mathematics), Conjunction (astronomy), Substorm, General Earth and Planetary Sciences, Ionosphere, 010502 geochemistry & geophysics, 01 natural sciences, 0105 earth and related environmental sciences
Abstract

著者人数: 23名, Accepted: 2018-08-30, 資料番号: SA1180143000

Published
2018

24. Substorm-Associated Ionospheric Flow Fluctuations During the 27 March 2017 Magnetic Storm: SuperDARN-Arase Conjunction

Author

Hori, T., Nishitani, N., Shepherd, S. G., Ruohoniemi, J. M., Connors, M., Teramoto, M., Nakano, S., Seki, K., Takahashi, N., Kasahara, S., Yokota, S., Mitani, T., Takashima, T., Higashio, N., Matsuoka, A., Asamura, K., Kazama, Y., Wang, S.-Y., Tam, S. W. Y., Chang, T.-F., Wang, B.-J., Miyoshi, Y., and Shinohara, I.

Subjects
ERG, Physics::Space Physics, substorm injection, SuperDARN, Physics::Atmospheric and Oceanic Physics, Physics::Geophysics, ULF wave, ring current electron, M‐I coupling
Abstract

Super Dual Auroral Radar Network (SuperDARN) observations show that ionospheric flow fluctuations of millihertz or lower‐frequency range with horizontal velocities of a few hundred meters per second appeared in the subauroral to midlatitude region during a magnetic storm on 27 March 2017. A set of the radars have provided the first ever observations that the fluctuations propagate azimuthally both westward and eastward simultaneously, showing bifurcated phase propagation associated with substorm expansion. Concurrent observations near the conjugate site in the inner magnetosphere made by the Arase satellite provide evidence that multiple drifting clouds of electrons in the near‐Earth equatorial plane were associated with the electric field fluctuations propagating eastward in the ionosphere. We interpret this event in terms of mesoscale pressure gradients carried by drifting ring current electrons that distort field lines one after another as they drift through the inner magnetosphere, causing eastward propagating ionospheric electric field fluctuations., ファイル公開:2019-03-28

Published
2018

36. Large-scale Observations of a Subauroral Polarization Stream by Midlatitude SuperDARN Radars: Instantaneous Longitudinal Velocity Variations

Author

Clausen, L. B. N, Baker, J. B. H, Sazykin, S, Ruohoniemi, J. M, Greenwald, R. A, Thomas, E. J, Shepherd, S. G, Talaat, E. R, Bristow, W. A, Zheng, Y, and Coster, A. J

Subjects
Space Sciences (General)
Abstract

We present simultaneous measurements of flow velocities inside a subauroral polarization stream (SAPS) made by six midlatitude high-frequency SuperDARN radars. The instantaneous observations cover three hours of universal time and six hours of magnetic local time (MLT). From velocity variations across the field-of-view of the radars we infer the local 2D flow direction at three different longitudes. We find that the local flow direction inside the SAPS channel is remarkably constant over the course of the event. The flow speed, however, shows significant temporal and spatial variations. After correcting for the radar look direction we are able to accurately determine the dependence of the SAPS velocity on magnetic local time. We find that the SAPS velocity variation with magnetic local time is best described by an exponential function. The average velocity at 00 MLT was 1.2 km/s and it decreased with a spatial e-folding scale of two hours of MLT toward the dawn sector. We speculate that the longitudinal distribution of pressure gradients in the ring current is responsible for this dependence and find these observations in good agreement with results from ring current models. Using TEC measurements we find that the high westward velocities of the SAPS are - as expected - located in a region of low TEC values, indicating low ionospheric conductivities.

Published
2012
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37. Polar Rain Gradients and Field-Aligned Polar Cap Potentials

Author

Fairfield, D. H, Wing, S, Newell, P. T, Ruohoniemi, J. M, Gosling, J. T, and Skoug, R. M

Subjects
Meteorology And Climatology
Abstract

ACE SWEPAM measurements of solar wind field-aligned electrons have been compared with simultaneous measurements of polar rain electrons precipitating over the polar cap and detected by DMSP spacecraft. Such comparisons allow investigation of cross-polarcap gradients in the intensity of otherwise-steady polar rain. The generally good agreement of the distribution functions, f, from the two data sources confirms that direct entry of solar electrons along open field lines is indeed the cause of polar rain. The agreement between the data sets is typically best on the side of the polar cap with most intense polar rain but the DMSP f's in less intense regions can be brought into agreement with ACE measurements by shifting all energies by a fixed amounts that range from tens to several hundred eV. In most cases these shifts are positive which implies that field-aligned potentials of these amounts exist on polar cap field lines which tend to retard the entry of electrons and produce the observed gradients. These retarding potentials undoubtedly appear in order to prevent the entry of low-energy electrons and maintain charge quasi-neutrality that would otherwise be violated since most tailward flowing magnetosheath ions are unable to follow polar rain electrons down to the polar cap. In more limited regions near the boundary of the polar cap there is sometimes evidence for field-aligned potentials of the opposite sign that accelerate polar rain electrons. A solar electron burst is also studied and it is concluded that electrons from such bursts can enter the magnetotail and precipitate in the same manner as polar rain.

Published
2008

39. The Spatial Variation of Polar Rain Electrons and its Cause

Author

Fairfield, D. H, Wing, S, Ruohoniemi, J. M, Newell, P. T, Gosling, J. T, and Skoug, R. M

Subjects
Space Sciences (General)
Abstract

It is generally accepted that field aligned electrons in the solar wind can follow field lines connected to Earth and precipitate in the polar ionosphere where they are known as polar rain. Few-hundred eV, field-aligned electrons of the solar wind "strahl" carry the interplanetary heat flux moving out from the sun and these electrons precipitate in either the northern or southern hemisphere depending on the magnetic field direction. These electrons produce enhanced polar rain in one hemisphere or the other although weaker polar rain is usually produced in the opposite hemisphere by whatever electrons are moving in the opposite direction. Although much evidence exists for this simple free entry mechanism, it has also long been known that there are spatial variations in the energies and intensities of the precipitating electrons. The present work compares electron distribution functions measured by the ACE spacecraft in the solar wind with those measured by the DMSP spacecraft at 800 km altitude over the polar cap. It is found that shifting the DMSP distribution functions in energy by amounts ranging from 10's to a few hundred eV produces quite good agreement with simultaneous ACE measurements. Over most of the polar cap this DMSP energy shift must be positive to achieve this agreement, suggesting the electrons have been decelerated by a field aligned potential as they move from the solar wind to low altitudes. The largest shifts occur on the nightside and on the dawn or dusk side, with the latter depending on the plasma convection pattern which is controlled by the orientation of the IMF. Nearer the cusp the shift is smaller or even negative. Since more massive tailward flowing magnetosheath ions are unable io follow the field lines into the magnetotail like the electrons, a field aligned potential is expected to develop to exclude low energy electrons and prevent an excessive charge imbalance. Such a potential would also produce the deceleration of those electrons that reach low altitudes. This improved understanding of polar rain should increase the utility of polar rain measurements as a diagnostic of the magnetosphere magnetic field configuration.

Published
2007

40. Purple Auroral Rays and Global Pc1 Pulsations Observed at the CIR‐Associated Solar Wind Density Enhancement on 21 March 2017

Author

Endo, Y., Connors, M., Schofield, I., Ruohoniemi, J. M., Baishev, D. G., Pashinin, A., Rakhmatulin, R., Shevtsov, B., Poddelsky, I., Engebretson, M., Raita, Tero, Fujimoto, A., Albert, Jay M., Shiokawa, Kazuo, Ozaki, Mitsunori, Kadokura, Akira, Sakanoi, T., Kurita, Satoshi, Miyoshi, Yoshizumi, Oyama, Shin-Ichiro, Nośe, Masahito, Nagatsuma, Tsutomu, Sakaguchi, Kaori, Tanaka, Yoshimasa, Shinohara, Manabu, Teramoto, Mariko, Nomura, Reiko, Matsuoka, Ayako, Higashio, Nana, Takashima, Takeshi, and Shinohara, Iku

Subjects
Physics, Solar wind, Geophysics, 010504 meteorology & atmospheric sciences, General Earth and Planetary Sciences, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, 0105 earth and related environmental sciences
Abstract

著者人数: 31名(所属. 宇宙航空研究開発機構宇宙科学研究所(JAXA)(ISAS): 松岡, 彩子; 高島, 健; 篠原, 育), Accepted: 2018-09-26, 資料番号: SA1180207000

Published
2018
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41. Interhemispheric observations of nightside ionospheric electric fields in response to IMF Bz and By changes and substorm pseudobreakup

Author

Yeoman, T. K., Lewis, R. V., Khan, H., Cowley, S. W. H., and Ruohoniemi, J. M.

Abstract

HF radar data during equinoctial, small IMF By conditions have enabled the ionospheric convection during the substorm growth phase and substorm pseudobreakup to be studied in both hemispheres. This has revealed both conjugate and non-conjugate convection behaviour during the substorm growth phase before and after the pseudobreakup onset. The nightside convection pattern is found to respond promptly to the southward turning of the interplanetary magnetic field (IMF) which impacts on the dusk flank of the magnetosphere due to an inclined phase front in the IMF in the case study presented. The subsequent interhemispheric observations of nightside convection are controlled by the IMF By polarity. The time scale for the response to changes in the IMF By component is found to be a little longer than for Bz, and the full impact of the IMF By is not apparent in the nightside convection until after substorm pseudobreakup has occurred. The pseudobreakup itself is found to result in a transitory suppression in the ionospheric electric field in both hemispheres. This flow suppression is very similar to that observed in HF radar observations of full substorm onset, with the exception of a lack of subsequent poleward expansion.Key words: Ionosphere (auroral ionosphere) - Magnetospheric physics (magnetosphere-ionosphere interactions; storms and substorms)

Published
2018

42. An assessment of the 'map-potential' and 'beam-swinging' techniques for measuring the ionospheric convection pattern using data from the SuperDARN radars

Author

Provan, G., Yeoman, T. K., Milan, S. E., Ruohoniemi, J. M., Barnes, R., and EGU, Publication

Subjects
[SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, Physics::Space Physics, [SDU.STU] Sciences of the Universe [physics]/Earth Sciences
Abstract

The SuperDARN HF coherent scatter radars (Greenwald et al., 1995) provide line-of-sight (l-o-s) velocity measurements of ionospheric convection flow over the polar regions of the northern and southern hemispheres. A number of techniques have been developed in order to obtain 2-D plasma flow vectors from these l-o-s observations. This study entails a comparison of the ionospheric flow vectors derived using the "map-potential", and "beam-swinging" techniques with the vectors derived using the "merging" technique. The merging technique is assumed to be the most accurate method of deriving local flow vectors from l-o-s velocities. We can conclude that the map-potential model is significantly more successful than the beam-swinging technique at estimating both the magnitude and the direction of the large-scale ionospheric convection flow vectors. The quality of the fit is dependent on time of day, with vectors observed at low latitudes in the dawn sector agreeing most closely with the merged vector flow pattern.Key words. Ionosphere (plasma convection; instruments and techniques) – Radio science (instruments and techniques)

Published
2018

47. Global Diagnostics of Ionospheric Absorption During X‐Ray Solar Flares Based on 8‐ to 20‐MHz Noise Measured by Over‐the‐Horizon Radars

Author

Berngardt, O. I., primary, Ruohoniemi, J. M., additional, St‐Maurice, J.‐P., additional, Marchaudon, A., additional, Kosch, M. J., additional, Yukimatu, A. S., additional, Nishitani, N., additional, Shepherd, S. G., additional, Marcucci, M. F., additional, Hu, H., additional, Nagatsuma, T., additional, and Lester, M., additional

Published
2019
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48. Polar Cap Plasma and Convection

Author

Elliott, Heather A, Craven, Paul D, Comfort, Richard H, Chandler, Michael O, Moore, Thomas E, and Ruohoniemi, J. M

Subjects
Geophysics
Abstract

This presentation will describe the character of the polar cap plasma in 10% AGU Spring 1998 particular the convection velocities at the perigee (about 1.8 Re) and apogee( about 8.9 Re) of Polar in relationship to Interplanetary Magnetic Field (IMF) and solar wind parameters. This plasma is thought to be due to several sources; the polar wind, cleft ion fountain, and auroral outflow. The plasma in the polar cap tends to be mostly field-aligned. At any given point in the polar cap, this plasma could be from a different regions since convection of magnetic field lines can transport this material. it is quite difficult to study such a phenomena with single point measurements. Current knowledge of the polar cap plasma obtained by in situ measurements will be presented along with recent results from the Polar mission. This study also examines the direct electrical coupling between the magnetosphere and ionosphere by comparing convection velocities measured by the Thermal Ion Dynamics Experiment (TIDE) and Magnetic Field Experiment (MFE) instruments in magnetosphere and measurements of the ionosphere by ground-based radars. At times such a comparison is difficult because the Polar satellite at apogee spends a large amount of time in the polar cap which is a region that is not coverage well by the current SuperDam coherent radars. This is impart due to the lack of irregularities that returns the radar signal.

Published
1998

49. Purple auroral rays and global Pc1 pulsations observed at the CIR‐associated solar wind density enhancement on 21 March 2017

Author

Shiokawa, K. (K.), Ozaki, M. (M.), Kadokura, A. (A.), Endo, Y. (Y.), Sakanoi, T. (T.), Kurita, S. (S.), Miyoshi, Y. (Y.), Oyama, S. -. (S. -I.), Connors, M. (M.), Schofield, I. (I.), Ruohoniemi, J. M. (J. M.), Nose, M. (M.), Nagatsuma, T. (T.), Sakaguchi, K. (K.), Baishev, D. G. (D. G.), Pashinin, A. (A.), Rakhmatulin, R. (R.), Shevtsov, B. (B.), Poddelsky, I. (I.), Engebretson, M. (M.), Raita, T. (Tero), Tanaka, Y. -. (Y. -M.), Shinohara, M. (M.), Teramoto, M. (M.), Nomura, R. (R.), Fujimoto, A. (A.), Matsuoka, A. (A.), Higashio, N. (N.), Takashima, T. (T.), Shinohara, I. (I.), Albert, J. M. (Jay M.), Shiokawa, K. (K.), Ozaki, M. (M.), Kadokura, A. (A.), Endo, Y. (Y.), Sakanoi, T. (T.), Kurita, S. (S.), Miyoshi, Y. (Y.), Oyama, S. -. (S. -I.), Connors, M. (M.), Schofield, I. (I.), Ruohoniemi, J. M. (J. M.), Nose, M. (M.), Nagatsuma, T. (T.), Sakaguchi, K. (K.), Baishev, D. G. (D. G.), Pashinin, A. (A.), Rakhmatulin, R. (R.), Shevtsov, B. (B.), Poddelsky, I. (I.), Engebretson, M. (M.), Raita, T. (Tero), Tanaka, Y. -. (Y. -M.), Shinohara, M. (M.), Teramoto, M. (M.), Nomura, R. (R.), Fujimoto, A. (A.), Matsuoka, A. (A.), Higashio, N. (N.), Takashima, T. (T.), Shinohara, I. (I.), and Albert, J. M. (Jay M.)

Abstract

This paper reports two unique auroral features: postmidnight purple auroral rays and global Pc1 geomagnetic pulsations, observed before the onset of the corotating interaction region (CIR) storm of 21 March 2017, at the beginning of the first campaign of the new Particles and Waves in the Inner magnetosphere using Ground‐based network observation (PWING) longitudinal ground network with the Arase satellite. The purple auroral rays were observed from ~0315 to 0430 UT (~03–04 magnetic local time) in the northeastern sky at Husafell, Iceland (magnetic latitude: 64.9°N). We newly propose that the entry of high‐density CIR plasma into the magnetotail created purple auroral rays in the sunlit ionosphere. Pc1 geomagnetic pulsations at frequencies of 0–0.5 Hz were observed after ~00 UT over a wide local time range, of 13 hr, from midnight to afternoon sectors at subauroral latitudes associated with CIR arrival. These results indicate preconditioning of the magnetosphere due to crossing of a CIR.

Published
2018

50. Observations of IMF and seasonal effects in high-latitude convection

Author

Ruohoniemi, J. M and Greenwald, R. A

Subjects
Geophysics
Abstract

Strong interplanetary magnetic field (IMF) and seasonal effects in the convection of nightside ionospheric plasma are described. The findings are based on a statistical analysis of observations made with the Johns Hopkins University/ Applied Physics Lab (JHU/APL) HF radar located at Goose Bay, Labrador. For positive sign of the IMF dusk-dawn component, By greater than 0 the dawn cell is more crescent shaped and the dusk cell more round while for BY less than 0 these pairings of size and shape are reversed. The more extreme crescent /round cell dichotomy is obtained for BY greater than 0. The return flows associated with the crescent-shaped cell dominate at midnight MLT (magnetic local time); the reversal in the zonal velocity in the 67 deg-69 deg lambda (magnetic latitude) interval occurs 2.5 hr earlier in summer than in winter. The maximum effects are obtained on the nightside for the pairings By greater than 0, summer and BY less than 0, winter; the first produces the more structured cell in the morning, the second in the evening, and this cell dominates the return flow at midnight. The difference in the zonal flow reversals for these pairings exceeds 4 hr in MLT.

Published
1995
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