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1. Detection of magnetospheric ion drift patterns at Mars

Author

Zhang, Chi, Nilsson, Hans, Ebihara, Yusuke, Yamauchi, Masatoshi, Persson, Moa, Rong, Zhaojin, Zhong, Jun, Dong, Chuanfei, Chen, Yuxi, Zhou, Xuzhi, Sun, Yixin, Harada, Yuki, Halekas, Jasper, Xu, Shaosui, Futaana, Yoshifumi, Shi, Zhen, Yuan, Chongjing, Yun, Xiaotong, Fu, Song, Gao, Jiawei, Holmström, Mats, Wei, Yong, and Barabash, Stas

Subjects
Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics
Abstract

Mars lacks a global magnetic field, and instead possesses small-scale crustal magnetic fields, making its magnetic environment fundamentally different from intrinsic magnetospheres like those of Earth or Saturn. Here we report the discovery of magnetospheric ion drift patterns, typical of intrinsic magnetospheres, at Mars usingmeasurements fromMarsAtmosphere and Volatile EvolutioNmission. Specifically, we observewedge-like dispersion structures of hydrogen ions exhibiting butterfly-shaped distributions within the Martian crustal fields, a feature previously observed only in planetary-scale intrinsic magnetospheres. These dispersed structures are the results of driftmotions that fundamentally resemble those observed in intrinsic magnetospheres. Our findings indicate that the Martian magnetosphere embodies an intermediate case where both the unmagnetized and magnetized ion behaviors could be observed because of the wide range of strengths and spatial scales of the crustal magnetic fields around Mars., Comment: 10 pages, 6 figures

Published
2023
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2. Plasma-neutral gas interactions in various space environments: Assessment beyond simplified approximations as a Voyage 2050 theme

Author

Yamauchi, Masatoshi, De Keyser, Johan, Parks, George, Oyama, Shin-ichiro, Wurz, Peter, Abe, Takumi, Beth, Arnaud, Daglis, Ioannis A., Dandouras, Iannis, Dunlop, Malcolm, Henri, Pierre, Ivchenko, Nickolay, Kallio, Esa, Kucharek, Harald, Liu, Yong C.-M., Mann, Ingrid, Marghitu, Octav, Nicolaou, Georgios, Rong, Zhaojin, Sakanoi, Takeshi, Saur, Joachim, Shimoyama, Manabu, Taguchi, Satoshi, Tian, Feng, Tsuda, Takuo, Tsurutani, Bruce, Turner, Drew, Ulich, Thomas, Yau, Andrew, and Yoshikawa, Ichiro

Published
2022
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3. The Energetic Oxygen Ion Beams in the Martian Magnetotail Current Sheets : Hints From the Comparisons Between Two Types of Current Sheets

Author

Zhang, Chi, Rong, Zhaojin, Li, Xinzhou, Fränz, Markus, Nilsson, Hans, Jarvinen, Riku, Persson, Moa, Futaana, Yoshifumi, Dong, Chuanfei, Yamauchi, Masatoshi, Gao, Jiawei, Zhou, Yijia, Wang, Lei, Shi, Zhen, Wei, Yong, He, Fei, Holmström, Mats, Barabash, Stas, Zhang, Chi, Rong, Zhaojin, Li, Xinzhou, Fränz, Markus, Nilsson, Hans, Jarvinen, Riku, Persson, Moa, Futaana, Yoshifumi, Dong, Chuanfei, Yamauchi, Masatoshi, Gao, Jiawei, Zhou, Yijia, Wang, Lei, Shi, Zhen, Wei, Yong, He, Fei, Holmström, Mats, and Barabash, Stas

Abstract

Using data from the Mars Atmosphere and Volatile EvolutioN (MAVEN) mission, we explore the plasma properties of Martian magnetotail current sheets (CS), to further understand the solar wind interaction with Mars and ion escape. There are some CS exhibit energetic oxygen ions that show narrow beam structures in the energy spectrum, which primarily occurs in the hemisphere where the solar wind electric field (Esw) is directed away from the planet. On average, these CS have a higher escaping flux than that of the CS without energetic oxygen ion beams, suggesting different roles in ion escape. The CS with energetic oxygen ion beams exhibits different proton and electron properties to the CS without energetic oxygen ion beams, indicating their different origins. Our analysis suggests that the CS with energetic oxygen ion beams may result from the interaction between the penetrated solar wind and localized oxygen ion plumes.

Published
2024
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4. Source of Drift-dispersed Electrons in Martian Crustal Magnetic Fields.

Author

Zhang, Chi, Zhou, Hongyang, Dong, Chuanfei, Harada, Yuki, Yamauchi, Masatoshi, Xu, Shaosui, Nilsson, Hans, Ebihara, Yusuke, Curry, Shannon M., Qin, Junfeng, Mitchell, David L., and Brain, David A.

Subjects
SOLAR magnetic fields, MARTIAN atmosphere, ELECTRON sources, SOLAR system, SOLAR wind
Abstract

Mars lacks a global intrinsic dipole field but possesses localized crustal fields, making it unique in the solar system. Recent observations revealed that electrons can be injected into the crustal fields, and exhibit drift-dispersed bursts due to the magnetic drift motion, which are characterized by increases or decreases in energy over time in the energy spectrum. However, the source of the drift-dispersed electrons and the mechanism of their injection into the crustal fields remains unclear. Here, by leveraging data from the Mars Atmosphere and Volatile EvolutioN mission, along with test-particle simulations, we reveal that the source of dispersed electrons is the precipitating electrons injected into the crustal fields via open field lines. These electrons display as dispersionless bursts near the source location, and as dispersed bursts as they drift away from the source. Thus, the dispersed electrons represent a later stage in the evolution of dispersionless electrons. This evolutionary process closely mirrors that observed within Earth's dipole field, affirming that the crustal fields function similarly to a mini-magnetosphere. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Detection of magnetospheric ion drift patterns at Mars

Author

Zhang, Chi, primary, Nilsson, Hans, additional, Ebihara, Yusuke, additional, Yamauchi, Masatoshi, additional, Persson, Moa, additional, Rong, Zhaojin, additional, Zhong, Jun, additional, Dong, Chuanfei, additional, Chen, Yuxi, additional, Zhou, Xuzhi, additional, Sun, Yixin, additional, Harada, Yuki, additional, Halekas, Jasper, additional, Xu, Shaosui, additional, Futaana, Yoshifumi, additional, Shi, Zhen, additional, Yuan, Chongjing, additional, Yun, Xiaotong, additional, Fu, Song, additional, Gao, Jiawei, additional, Holmström, Mats, additional, Wei, Yong, additional, and Barabash, Stas, additional

Published
2023
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8. Plasma-Neutral Interactions in the Lower Thermosphere-Ionosphere: The need for in situ measurements to address focused questions

Author

Sarris, Theodoros, primary, Aikio, Anita, additional, Buchert, Stephan, additional, Clilverd, Mark A., additional, Dandouras, Iannis, additional, Doornbos, Eelco, additional, Goodwin, Lindsay Victoria, additional, Grandin, Maxime, additional, Heelis, Roderick, additional, Ivchenko, Nickolay, additional, Jorgensen, Therese, additional, Kervalishvili, Guram, additional, Knudsen, David, additional, Liu, Han-Li, additional, Lu, Gang, additional, Malaspina, David M., additional, Marghitu, Octav, additional, Maute, Astrid, additional, Miloch, Wojciech J., additional, Olsen, Nils, additional, Palmroth, Minna, additional, Pfaff, Robert, additional, Stolle, Claudia, additional, Talaat, Elsayed, additional, Thayer, Jeffrey P., additional, Tourgaidis, Stelios, additional, Verronen, Pekka, additional, Yamauchi, Masatoshi, additional, Bruinsma, Sean, additional, Harding, Brian, additional, Lynch, Kristina, additional, Marchaudon, Aurélie, additional, Mehta, Piyush M., additional, Ozturk, Dogacan Su, additional, Perry, Gareth, additional, Pilinski, Marcin, additional, Siemes, Christian, additional, Visser, Pieter, additional, and Vogt, Joachim, additional

Published
2023
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9. Discovery of Intrinsic Magnetospheric Ion Behavior at Mars

Author

Rong, Zhaojin, primary, Zhang, Chi, additional, Nilsson, Hans, additional, Ebihara, Yusuke, additional, Yamauchi, Masatoshi, additional, Persson, Moa, additional, Zhong, Jun, additional, Dong, Chuanfei, additional, Chen, Yuxi, additional, Zhou, Xuzhi, additional, Sun, Yixin, additional, Harada, Yuki, additional, Halekas, Jasper, additional, Xu, Shaosui, additional, Futaana, Yoshifumi, additional, Shi, Zhen, additional, Yuan, Chongjing, additional, Yun, Xiaotong, additional, Fu, Song, additional, Gao, Jiawei, additional, Holmstrom, Mats, additional, Wei, Yong, additional, and Barabash, Stanislav, additional

Published
2023
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11. Plasma-neutral interactions in the lower thermosphere-ionosphere : The need for in situ measurements to address focused questions

Author

Sarris, Theodoros, Palmroth, Minna, Aikio, Anita, Buchert, Stephan Christoph, Clemmons, James, Clilverd, Mark, Dandouras, Iannis, Doornbos, Eelco, Goodwin, Lindsay Victoria, Grandin, Maxime, Heelis, Roderick, Ivchenko, Nickolay, Moretto-Jørgensen, Therese, Kervalishvili, Guram, Knudsen, David, Liu, Han-Li, Lu, Gang, Malaspina, David M., Marghitu, Octav, Maute, Astrid, Miloch, Wojciech J., Olsen, Nils, Pfaff, Robert, Stolle, Claudia, Talaat, Elsayed, Thayer, Jeffrey, Tourgaidis, Stelios, Verronen, Pekka T., Yamauchi, Masatoshi, Sarris, Theodoros, Palmroth, Minna, Aikio, Anita, Buchert, Stephan Christoph, Clemmons, James, Clilverd, Mark, Dandouras, Iannis, Doornbos, Eelco, Goodwin, Lindsay Victoria, Grandin, Maxime, Heelis, Roderick, Ivchenko, Nickolay, Moretto-Jørgensen, Therese, Kervalishvili, Guram, Knudsen, David, Liu, Han-Li, Lu, Gang, Malaspina, David M., Marghitu, Octav, Maute, Astrid, Miloch, Wojciech J., Olsen, Nils, Pfaff, Robert, Stolle, Claudia, Talaat, Elsayed, Thayer, Jeffrey, Tourgaidis, Stelios, Verronen, Pekka T., and Yamauchi, Masatoshi

Abstract

The lower thermosphere-ionosphere (LTI) is a key transition region between Earth’s atmosphere and space. Interactions between ions and neutrals maximize within the LTI and in particular at altitudes from 100 to 200 km, which is the least visited region of the near-Earth environment. The lack of in situ co-temporal and co-spatial measurements of all relevant parameters and their elusiveness to most remote-sensing methods means that the complex interactions between its neutral and charged constituents remain poorly characterized to this date. This lack of measurements, together with the ambiguity in the quantification of key processes in the 100–200 km altitude range affect current modeling efforts to expand atmospheric models upward to include the LTI and limit current space weather prediction capabilities. We present focused questions in the LTI that are related to the complex interactions between its neutral and charged constituents. These questions concern core physical processes that govern the energetics, dynamics, and chemistry of the LTI and need to be addressed as fundamental and long-standing questions in this critically unexplored boundary region. We also outline the range of in situ measurements that are needed to unambiguously quantify key LTI processes within this region, and present elements of an in situ concept based on past proposed mission concepts.

Published
2023
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15. Plasma-neutral gas interactions in various space environments beyond simplified approximations

Author

Yamauchi, Masatoshi, primary, De Keyser, Johan, additional, Parks, George, additional, Oyama, Shin-ichiro, additional, Wurz, Peter, additional, Abe, Takumi, additional, Beth, Arnaud, additional, Dunlop, Malcolm, additional, Henri, Pierre, additional, Kucharek, Harald, additional, Marghitu, Octav, additional, Nicolaou, Georgios, additional, Shimoyama, Manabu, additional, Saur, Joachim, additional, Taguchi, Satoshi, additional, Tsuda, Takuo, additional, and Tsurutani, Bruce, additional

Published
2023
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24. The fate of O⁺ ions observed in the plasma mantle and cusp: particle tracing modelling and Cluster observations

Author

Schillings, Audrey, Gunell, Herbert, Nilsson, Hans, Spiegeleer, Alexandre, Ebihara, Yusuke, Westerberg, Lars G., Yamauchi, Masatoshi, and Slapak, Rikard

Subjects
Physics::Plasma Physics, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Physics::Geophysics
Abstract

Ion escape is of particular interest for studying the evolution of the atmosphere on geological time scales. Previously, using Cluster-CODIF data, we investigated the oxygen ion outflow from the plasma mantle for different solar wind conditions and geomagnetic activity. We found significant correlations between solar wind parameters, geomagnetic activity (Kp index) and the O+ outflow. From these studies, we suggested that O+ ions observed in the plasma mantle and cusp have enough energy and velocity to escape the magnetosphere and be lost into the solar wind or in the distant magnetotail. Thus, this study aims to investigate where do the ions observed in the plasma mantle end up. In order to answer this question, we numerically calculate the trajectories of O+ ions using a tracing code to further test this assumption and determine the fate of the observed ions. Our code consists of a magnetic field model (Tsyganenko T96) and an ionospheric potential model (Weimer 2001) in which particles initiated in the plasma mantle and cusp regions are launched and traced forward in time. We analysed 136 observations of plasma mantle or cusp events in Cluster data between 2001 and 2007, and for each event 200 O+ particles were launched with an initial parallel and perpendicular velocity corresponding to the bulk velocity observed by Cluster. From the observations, our results show that 93 % of the events have an initial parallel velocity component twice the initial perpendicular velocity. After the tracing, we found that 96 % of the particles are lost into the solar wind or in the distant tail. Out of these 96 %, 20 % escape into the dayside magnetosphere.

Published
2020

25. 宇宙地球結合系機構の直接探査に向けたFACTORS計画の概要

Author

HIRAHARA, Masafumi, SAITO, Yoshifumi, KOJIMA, Hirotsugu, ASAMURA, Kazushi, SAKANOI, Takeshi, MIYOSHI, Yoshizumi, KITAMURA, Naritoshi, and YAMAUCHI, Masatoshi

Abstract

第22回宇宙科学シンポジウム (2022年1月6日-7日. オンライン開催), 22nd Space Science Symposium (January 6-7, 2022. Online Meeting), 資料番号: SA6000176007, レポート番号: S2-002

Published
2022

27. Molecular and metalic ions in the magnetosphere: ISSI team preliminary results 

Author

Yamauchi, Masatoshi, primary, Dandouras, Iannis, additional, Mann, Ingrid, additional, Haaland, Stein, additional, Würz, Peter, additional, Plane, John, additional, Kastinen, Daniel, additional, Gunnarsdottir, Tinna, additional, Yau, Andrew, additional, Kistler, Lynn, additional, Hamilton, Doug, additional, Christon, Steve, additional, Saito, Yoshufumi, additional, Watanabe, Shigeto, additional, and Nozawa, Satonori, additional

Published
2022
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30. Auroral alert version 1.0: two-step automatic detection of sudden aurora intensification from all-sky JPEG images.

Author

Yamauchi, Masatoshi and Brändström, Urban

Subjects
*AURORAS, *JPEG (Image coding standard), *COLOR codes, *OXYGEN, *LIGHT sources, *PIXELS, *SEXTING
Abstract

A sudden and significant intensification of the auroral arc with expanding motion (we call it "local-arc breaking" hereafter) is an important event in many aspects but easy to miss for real-time watching due to its short rise time. To ease this problem, a real-time alert system for local-arc breaking was developed for the Kiruna all-sky camera (ASC) using ASC images in the JPEG format. The identification of the local-arc breaking is made in two steps using the "expert system" in both steps: (1) explicit criteria for classification of each pixel and simple calculations afterward are applied to each ASC image to obtain a simple set of numbers, or the "ASC auroral index", representing the occupancy of aurora pixels and characteristic intensity of the brightest aurora in the image; (2) using this ASC auroral index, the level of auroral activity is estimated, aiming for Level 6 as clear local-arc breaking and Level 4 as a precursor for it (reserving Levels 1–3 for less active aurora and Level 5 for less intense sudden intensification). The first step is further divided into two stages. Stage (1a) uses simple criteria for R (red), G (green), and B (blue) values in the RGB color code and the H (hue) value calculated from these RGB values, each pixel of a JPEG image is classified into three aurora categories (from brightest to faintest, "strong aurora", "green arc", and "visible diffuse (aurora)") and three non-aurora light source categories ("cloud", "artificial light", and "Moon"). Here, strong aurora means that the ordinary green color by atomic oxygen's 558 nm emission is either nearly saturated or mixed with red color at around 670 nm emitted, by molecular nitrogen. In stage (1b), the percentage of the occupying area (pixel coverage) for each category and the characteristic intensity of the strong aurora pixels are calculated. The obtained ASC auroral index is posted in both an ASCII format and plots in real time (https://www.irf.se/alis/allsky/nowcast/ , last access: 11 April 2023). When Level 6 (local-arc breaking) is detected, an automatic alert email is sent out to the registered addresses immediately. The alert system started on 5 November 2021, and the results (both Level 6 detection and Level 4 detection) were compared to the manual (eye) identification of the auroral activity in the ASC during the rest of the aurora season of the Kiruna ASC (i.e., all images during a total of 5 months until April 2022 were examined and occasionally double-checked in the sky). Unless the Moon or the cloud blocks the brightened region, a nearly one-to-one correspondence between Level 6 and eye-identified local-arc breaking in the ASC images is achieved with an uncertainty of under 10 min. [ABSTRACT FROM AUTHOR]

Published
2023
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32. Current Status of the FACTORS mission for Exploring the Space-Earth Coupling System: Spacecraft Configuration for Formation Flight and Orbital Disturbance and Control

Author

HIRAHARA, Masafumi, SAITO, Yoshifumi, KOJIMA, Hirotsugu, ASAMURA, Kazushi, YAMAUCHI, Masatoshi, SAKANOI, Takeshi, MIYOSHI, Yoshizumi, KITAMURA, Naritoshi, and SUGIMOTO, Toshihide

Abstract

第21回宇宙科学シンポジウム (2021年1月6日-7日. オンライン開催), 21st Space Science Symposium (January 6-7, 2021. Online Meeting), 資料番号: SA6000163138, レポート番号: g25-1

Published
2021

33. Lower-thermosphere–ionosphere (LTI) quantities: current status of measuring techniques and models

Author

Palmroth, Minna, Grandin, Maxime, Sarris, Theodoros, Doornbos, Eelco, Tourgaidis, Stelios, Aikio, Anita, Buchert, Stephan, Clilverd, Mark A., Dandouras, Iannis, Heelis, Roderick, Hoffmann, Alex, Ivchenko, Nickolay, Kervalishvili, Guram, Knudsen, David J., Kotova, Anna, Liu, Han-Li, Malaspina, David M., March, Günther, Marchaudon, Aurélie, Marghitu, Octav, Matsuo, Tomoko, Miloch, Wojciech J., Moretto-Jørgensen, Therese, Mpaloukidis, Dimitris, Olsen, Nils, Papadakis, Konstantinos, Pfaff, Robert, Pirnaris, Panagiotis, Siemes, Christian, Stolle, Claudia, Suni, Jonas, van den IJssel, Jose, Verronen, Pekka T., Visser, Pieter, Yamauchi, Masatoshi, Department of Physics, Space Physics Research Group, and Particle Physics and Astrophysics

Subjects
EQUATORIAL SPREAD-F, ENERGETIC PARTICLE-PRECIPITATION, TOTAL ELECTRON-CONTENT, INTERPLANETARY MAGNETIC-FIELD, SOLAR-WIND, GLOBAL MHD SIMULATION, 115 Astronomy, Space science, HIGH-LATITUDINAL IONOSPHERE, FIELD-ALIGNED CURRENTS, GRAVITY-WAVE, POYNTING FLUX
Abstract

The lower-thermosphere–ionosphere (LTI) system consists of the upper atmosphere and the lower part of the ionosphere and as such comprises a complex system coupled to both the atmosphere below and space above. The atmospheric part of the LTI is dominated by laws of continuum fluid dynamics and chemistry, while the ionosphere is a plasma system controlled by electromagnetic forces driven by the magnetosphere, the solar wind, as well as the wind dynamo. The LTI is hence a domain controlled by many different physical processes. However, systematic in situ measurements within this region are severely lacking, although the LTI is located only 80 to 200 km above the surface of our planet. This paper reviews the current state of the art in measuring the LTI, either in situ or by several different remote-sensing methods. We begin by outlining the open questions within the LTI requiring high-quality in situ measurements, before reviewing directly observable parameters and their most important derivatives. The motivation for this review has arisen from the recent retention of the Daedalus mission as one among three competing mission candidates within the European Space Agency (ESA) Earth Explorer 10 Programme. However, this paper intends to cover the LTI parameters such that it can be used as a background scientific reference for any mission targeting in situ observations of the LTI. publishedVersion

Published
2021

34. Lower-Thermosphere-ionosphere (LTI) quantities:Current status of measuring techniques and models

Author

Palmroth, Minna, Grandin, Maxime, Sarris, Theodoros, Doornbos, Eelco, Tourgaidis, Stelios, Aikio, Anita, Buchert, Stephan, Clilverd, Mark A., Dandouras, Iannis, Heelis, Roderick, Hoffmann, Alex, Ivchenko, Nickolay, Kervalishvili, Guram, Knudsen, David J., Kotova, Anna, Liu, Han Li, Malaspina, David M., March, Gönther, Marchaudon, Aurélie, Marghitu, Octav, Matsuo, Tomoko, Miloch, Wojciech J., Moretto-Jørgensen, Therese, Mpaloukidis, Dimitris, Olsen, Nils, Papadakis, Konstantinos, Pfaff, Robert, Pirnaris, Panagiotis, Siemes, Christian, Stolle, Claudia, Suni, Jonas, Van Den Ijssel, Jose, Verronen, Pekka T., Visser, Pieter, Yamauchi, Masatoshi, Palmroth, Minna, Grandin, Maxime, Sarris, Theodoros, Doornbos, Eelco, Tourgaidis, Stelios, Aikio, Anita, Buchert, Stephan, Clilverd, Mark A., Dandouras, Iannis, Heelis, Roderick, Hoffmann, Alex, Ivchenko, Nickolay, Kervalishvili, Guram, Knudsen, David J., Kotova, Anna, Liu, Han Li, Malaspina, David M., March, Gönther, Marchaudon, Aurélie, Marghitu, Octav, Matsuo, Tomoko, Miloch, Wojciech J., Moretto-Jørgensen, Therese, Mpaloukidis, Dimitris, Olsen, Nils, Papadakis, Konstantinos, Pfaff, Robert, Pirnaris, Panagiotis, Siemes, Christian, Stolle, Claudia, Suni, Jonas, Van Den Ijssel, Jose, Verronen, Pekka T., Visser, Pieter, and Yamauchi, Masatoshi

Abstract

The lower-Thermosphere-ionosphere (LTI) system consists of the upper atmosphere and the lower part of the ionosphere and as such comprises a complex system coupled to both the atmosphere below and space above. The atmospheric part of the LTI is dominated by laws of continuum fluid dynamics and chemistry, while the ionosphere is a plasma system controlled by electromagnetic forces driven by the magnetosphere, the solar wind, as well as the wind dynamo. The LTI is hence a domain controlled by many different physical processes. However, systematic in situ measurements within this region are severely lacking, although the LTI is located only 80 to 200 km above the surface of our planet. This paper reviews the current state of the art in measuring the LTI, either in situ or by several different remote-sensing methods. We begin by outlining the open questions within the LTI requiring high-quality in situ measurements, before reviewing directly observable parameters and their most important derivatives. The motivation for this review has arisen from the recent retention of the Daedalus mission as one among three competing mission candidates within the European Space Agency (ESA) Earth Explorer 10 Programme. However, this paper intends to cover the LTI parameters such that it can be used as a background scientific reference for any mission targeting in situ observations of the LTI..

Published
2021

35. Synthesis of studies on significant atmospheric electrical effects of major nuclear accidents in Chernobyl and Fukushima

Author

Dragović, Snežana D., Yamauchi, Masatoshi, Aoyama, Michio, Kajino, Mizuo, Petrović, Jelena M., Ćujić, Mirjana, Dragović, Ranko, Đorđević, Milan, and Bór, József

Abstract

Radioactive materials released during the two most serious nuclear accidents in history, at Chernobyl and Fukushima, caused exceptionally significant contamination and perturbations of the environment. Among them, this paper focuses on the effects related to the atmospheric electricity (AE). Measurements of the most significant disturbances in the values of various AE parameters recorded near ground level are reviewed and the corresponding results are jointly evaluated. The Chernobyl and Fukushima events caused changes in the AE parameters both after long-distance transport (Chernobyl) and short-distance transport including re-suspension (Fukushima). The data indicates that the electrical conductivity of the air is more sensitive to the presence of airborne radioactivity than the atmospheric electric potential gradient (PG). PG, on the other hand, can be monitored more easily and its variation also reflects the vertical redistribution of radionuclides in the air due to their transport, deposition, and re-suspension from the ground. A brief overview of studies on atmospheric transport and deposition of radioactive clouds is given to facilitate the importance of considering the AE measurements in these subjects, and to incorporate those studies in interpreting the results of AE measurements. The AE measurements are particularly important in studying microphysical effects of enhanced radioactivity in the air where no other distance monitoring method exists, both for fair weather conditions wet conditions.

Published
2020

36. The fate of O+ ions observed in the plasma mantle : particle tracing modelling and cluster observations

Author

Schillings, Audrey, Gunell, Herbert, Nilsson, Hans, Spiegeleer, Alexandre, Ebihara, Yusuke, Westerberg, Lars G., Yamauchi, Masatoshi, and Slapak, Rikard

Subjects
Fusion, plasma och rymdfysik, Physics::Plasma Physics, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Fusion, Plasma and Space Physics, Physics::Geophysics
Abstract

Ion escape is of particular interest for studying the evolution of the atmosphere on geological timescales. Previously, using Cluster-CODIF data, we investigated the oxygen ion outflow from the plasma mantle for different solar wind conditions and geomagnetic activity. We found significant correlations between solar wind parameters, geomagnetic activity (Kp index), and the O+ outflow. From these studies, we suggested that O+ ions observed in the plasma mantle and cusp have enough energy and velocity to escape the magnetosphere and be lost into the solar wind or in the distant magnetotail. Thus, this study aims to investigate where the ions observed in the plasma mantle end up. In order to answer this question, we numerically calculate the trajectories of O+ ions using a tracing code to further test this assumption and determine the fate of the observed ions. Our code consists of a magnetic field model (Tsyganenko T96) and an ionospheric potential model (Weimer 2001) in which particles initiated in the plasma mantle region are launched and traced forward in time. We analysed 131 observations of plasma mantle events in Cluster data between 2001 and 2007, and for each event 200 O+ particles were launched with an initial thermal and parallel bulk velocity corresponding to the velocities observed by Cluster. After the tracing, we found that 98 % of the particles are lost into the solar wind or in the distant tail. Out of these 98 %, 20 % escape via the dayside magnetosphere.

Published
2020

37. The fate of O⁺ ions observed in the plasma mantle and cusp: particle tracing modelling and Cluster observations

Author

80342616, Schillings, Audrey, Gunell, Herbert, Nilsson, Hans, De Spiegeleer, Alexandre, Ebihara, Yusuke, Westerberg, Lars G., Yamauchi, Masatoshi, Slapak, Rikard, 80342616, Schillings, Audrey, Gunell, Herbert, Nilsson, Hans, De Spiegeleer, Alexandre, Ebihara, Yusuke, Westerberg, Lars G., Yamauchi, Masatoshi, and Slapak, Rikard

Abstract

Ion escape is of particular interest for studying the evolution of the atmosphere on geological timescales. Previously, using Cluster-CODIF data, we investigated the oxygen ion outflow from the plasma mantle for different solar wind conditions and geomagnetic activity. We found significant correlations between solar wind parameters, geomagnetic activity (Kp index), and the O⁺ outflow. From these studies, we suggested that O⁺ ions observed in the plasma mantle and cusp have enough energy and velocity to escape the magnetosphere and be lost into the solar wind or in the distant magnetotail. Thus, this study aims to investigate where the ions observed in the plasma mantle end up. In order to answer this question, we numerically calculate the trajectories of O⁺ ions using a tracing code to further test this assumption and determine the fate of the observed ions. Our code consists of a magnetic field model (Tsyganenko T96) and an ionospheric potential model (Weimer 2001) in which particles initiated in the plasma mantle region are launched and traced forward in time. We analysed 131 observations of plasma mantle events in Cluster data between 2001 and 2007, and for each event 200 O⁺ particles were launched with an initial thermal and parallel bulk velocity corresponding to the velocities observed by Cluster. After the tracing, we found that 98 % of the particles are lost into the solar wind or in the distant tail. Out of these 98 %, 20 % escape via the dayside magnetosphere.

Published
2020

38. High-latitude crochet:Solar-flare-induced magnetic disturbance independent from low-latitude crochet

Author

Yamauchi, Masatoshi, Johnsen, Magnar G., Enell, Carl Fredrik, Tjulin, Anders, Willer, Anna, Sormakov, Dmitry A., Yamauchi, Masatoshi, Johnsen, Magnar G., Enell, Carl Fredrik, Tjulin, Anders, Willer, Anna, and Sormakov, Dmitry A.

Abstract

A solar-flare-induced, high-latitude (peak at 70- 75 geographic latitude - GGlat) ionospheric current system was studied. Right after the X9.3 flare on 6 September 2017, magnetic stations at 68-77 GGlat near local noon detected northward geomagnetic deviations (1B) for more than 3 h, with peak amplitudes of > 200 nT without any accompanying substorm activities. From its location, this solar flare effect, or crochet, is different from previously studied ones, namely, the subsolar crochet (seen at lower latitudes), auroral crochet (pre-requires auroral electrojet in sunlight), or cusp crochet (seen only in the cusp). The new crochet is much more intense and longer in duration than the subsolar crochet. The long duration matches with the period of high solar X-ray flux (more than M3-class flare level). Unlike the cusp crochet, the interplanetary magnetic field (IMF) BY is not the driver, with the BY values of only 0-1 nT out of a 3 nT total field. The equivalent ionospheric current flows eastward in a limited latitude range but extended at least 8 h in local time (LT), forming a zonal current region equatorward of the polar cap on the geomagnetic closed region. EISCAT radar measurements, which were conducted over the same region as the most intense 1B, show enhancements of electron density (and hence of ion-neutral density ratio) at these altitudes (100 km) at which strong background ion convection (> 100ms-1) pre-existed in the direction of tidal-driven diurnal solar quiet (Sq0) flow. Therefore, this new zonal current can be related to this Sq0-like convection and the electron density enhancement, for example, by descending the E-region height. However, we have not found why the new crochet is found in a limited latitudinal range, and therefore, the mechanism is still unclear compared to the subsolar crochet that is maintained by a transient redistribution of the electron density. The signature is sometimes seen in the auroral electrojet (AEDAU-AL) index. A q

Published
2020

41. Auroral alert version 1.0: Two-step automatic detection of sudden auroral intensification from all-sky jpeg images.

Author

Yamauchi, Masatoshi and Brändström, Urban

Subjects
CAMERAS, AUTOMATIC detection in radar, IMAGE analysis, PIXELS, UNCERTAINTY
Abstract

A real-time alert system of sudden and significant intensification of auroral arc with expanding motion (we call it "Local-Arc-Breaking" hereafter) was developed for Kiruna all-sky camera (ASC) using ASC jpeg images. The identification is made in two steps: (1) Using an "expert system" in which a combinations of simple criteria is applied to each pixels with calculations afterward (expert system), each jpeg image of the ASC is converted into a simple set of numbers, or "ASC auroral index", representing the occupancy of auroral pixels and characteristic intensity of the brightest aurora in the image. (2) Using this ASC auroral index, the level of auroral activity is estimated, aiming Level 6 as clear Local-Arc-Breaking and Level 4 as precursor for it (reserving Levels 1-3 for less active aurorae). The first step is further divided into two stages: (1a) Using simple criteria for R (red), G (green), B (blue), and H (hue) values in the RGB and HLS colour codes, each pixel of a jpeg image is classified into several categories according to its colour as "visible diffuse", "green arc", "strong aurora" (which means saturated or mixed with N2 red line at 670 nm), "cloud", "artificial light", and "moon". (1b) The percentage of the occupying area (pixel coverage) for each category and the characteristic intensity of "strong aurora" are calculated. The obtained ASC aurora index is posted in both a ascii format and plots on a real-time bases at https://www.irf.se/alis/allsky/nowcast/. When Level 6 is detected, automatic alert E-mail is sent out to the registered addresses immediately. The alert system started 5 November, 2021, and the results (both Level 6 detection and Level 4 detection) were compared to the manual eye-)identification of the auroral activity during the rest of the auroral season of Kiruna ASC (i.e., total five months until April 2022). Unless the Moon or cloud blocks the brightened region, nearly one-to-one correspondence between Level 6 and Local-Arc-Breaking judged by original ASC images is achieved within ten minutes uncertainty. [ABSTRACT FROM AUTHOR]

Published
2022
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47. Lower thermosphere – ionosphere (LTI) quantities: Current status of measuring techniques and models

Author

Palmroth, Minna, primary, Grandin, Maxime, additional, Sarris, Theodoros, additional, Doornbos, Eelco, additional, Tourgaidis, Stelios, additional, Aikio, Anita, additional, Buchert, Stephan, additional, Clilverd, Mark A., additional, Dandouras, Iannis, additional, Heelis, Roderick, additional, Hoffmann, Alex, additional, Ivchenko, Nickolay, additional, Kervalishvili, Guram, additional, Knudsen, David J., additional, Kotova, Anna, additional, Liu, Han-Li, additional, Malaspina, David M., additional, March, Günther, additional, Marchaudon, Aurélie, additional, Marghitu, Octav, additional, Matsuo, Tomoko, additional, Miloch, Wojciech J., additional, Moretto-Jørgensen, Therese, additional, Mpaloukidis, Dimitris, additional, Olsen, Nils, additional, Papadakis, Konstantinos, additional, Pfaff, Robert, additional, Pirnaris, Panagiotis, additional, Siemes, Christian, additional, Stolle, Claudia, additional, Suni, Jonas, additional, van den IJssel, Jose, additional, Verronen, Pekka T., additional, Visser, Pieter, additional, and Yamauchi, Masatoshi, additional

Published
2020
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