Your search keyword '"transpolar arc"' showing total 14 results

1. Magnetospheric Sources of Theta Aurora: A Case Study Comparing Observations With SWMF Global Simulation.

Author

Hill, S. C., Pulkkinen, T. I., Brenner, A., Al Shidi, Q., Mukhopadhyay, A., Kullen, A., Frey, H., Zou, S., and Liemohn, M.

Subjects

*SOLAR magnetic fields, *SOLAR wind, *GEOMAGNETISM, *AURORAS, *SPACE environment, *OUTER space, *CURRENT sheets, *HELIOSEISMOLOGY

Abstract

We present the first high resolution global MHD with coupled inner magnetosphere simulation results of an observed theta aurora event. We use the Space Weather Modeling Framework in the Geospace configuration, which produces accurate field aligned current closure in the ionosphere that is integral to theta aurora formation. At the location of the observed theta aurora, the simulation produces a narrow channel of Joule heating along both open and closed field lines, and between a pair of oppositely directed field‐aligned current sheets in the ionosphere. We demonstrate that this Joule heating pattern that we identify as theta aurora maps to a reconnection region at the magnetotail flanks as well as in the distant magnetotail. The theta aurora maps to a cross‐tail current disruption and field‐aligned current source region in a highly twisted magnetotail. Plain Language Summary: The light of the aurora observed in the Earth's atmosphere is a signature of magnetic processes in outer space. The Sun produces hot magnetized plasma that blows through the solar system like a wind. The Earth's magnetic field shields us from the harmful impacts of the Sun's magnetized plasma wind. The interaction between the Earth's magnetic field and the Sun's plasma wind causes the ring of auroral light we see in the polar regions. Sometimes the ring of auroral light grows a bar of auroral light across its center (over the Earth's magnetic poles), transforming the ring into a structure like the Greek letter theta. We call this the theta aurora. It is unknown what physical processes in the Earth's magnetic field create the theta aurora. In this study we show the first realistic simulation that uses solar wind driver conditions of an observed theta aurora event, and demonstrate that we can successfully produce the theta aurora structure in the simulation. We find that the theta aurora's center bar of auroral light comes from multiple regions in the vast Earth's magnetotail. This new result helps us better understand the dynamics of the Earth's space environment and better protect ourselves against the Sun's hazardous plasma wind effects. Key Points: We show first global MHD simulation event study that successfully produces a Joule heating signature that we identify as theta auroraSimulation associates transpolar arc signatures with reconnection at the magnetospheric flank and in the distant magnetotailThe transpolar arc maps to a cross‐tail current disruption and field‐aligned current source region in a highly twisted magnetotail [ABSTRACT FROM AUTHOR]

Published

2024

2. Evolution of a long-duration transpolar arc during very quiet period.

Author

Fei He, Xiao-Xin Zhang, Jiawei Li, Zhonghua Yao, Zhaojin Rong, Yong Wei, Desheng Han, and Jianjun Liu

Subjects

*INTERPLANETARY magnetic fields, *PLASMA instabilities, *METEOROLOGICAL satellites, *MAGNETIC fields, *PARTICLE dynamics, *THERMAL instability

Abstract

In this study, we explore the evolution of long-duration transpolar arcs observed during an exceptionally quiet period by the Fengyun-3D and Defense Meteorological Satellite Program satellites on 17 January 2019. Leveraging the extensive field of view of WAI, we captured the complete structure and evolution of the TPA over a very quiet period exceeding 7 h, with AE<30 nT. The TPA initially manifested at the poleward boundary of the auroral oval in the dawn sector, gradually migrating towards the dusk as the y-component of the interplanetary magnetic field (IMF BY) transitioned from negative to positive. Throughout this phase, the TPA underwent a distortion, transforming from a straight line to an "l-shape". Following a reversal in interplanetary magnetic field BY to negative, the TPA retraced its path towards dawn and ultimately dissipated when the IMF turned southward. Of particular interest is the observation that when the TPA approached the noon-midnight line, small-scale spiral structures became apparent within the TPA. This suggests the presence of intricate small-scale magnetic field topologies or plasma instabilities/shears in the source region. These observations highlight the likelihood of complex field and particle dynamics in the high-latitude reconnection region and the twisted tail plasma sheet. [ABSTRACT FROM AUTHOR]

Published

2024

3. Magnetospheric Sources of Theta Aurora: A Case Study Comparing Observations With SWMF Global Simulation

Author

S. C. Hill, T. I. Pulkkinen, A. Brenner, Q. Al Shidi, A. Mukhopadhyay, A. Kullen, H. Frey, S. Zou, and M. Liemohn

Subjects

theta aurora, magnetotail, ionosphere, simulation, transpolar arc, reconnection, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract We present the first high resolution global MHD with coupled inner magnetosphere simulation results of an observed theta aurora event. We use the Space Weather Modeling Framework in the Geospace configuration, which produces accurate field aligned current closure in the ionosphere that is integral to theta aurora formation. At the location of the observed theta aurora, the simulation produces a narrow channel of Joule heating along both open and closed field lines, and between a pair of oppositely directed field‐aligned current sheets in the ionosphere. We demonstrate that this Joule heating pattern that we identify as theta aurora maps to a reconnection region at the magnetotail flanks as well as in the distant magnetotail. The theta aurora maps to a cross‐tail current disruption and field‐aligned current source region in a highly twisted magnetotail.

Published

2024

4. 3D GUMICS Simulations of Northward IMF Magnetotail Structure.

Author

Fryer, L. J., Fear, R. C., Gingell, I. L., Coxon, J. C., Palmroth, M., Hoilijoki, S., Janhunen, P., Kullen, A., and Cassak, P. A.

Subjects

INTERPLANETARY magnetic fields, SOLAR magnetic fields, MAGNETOSPHERE, SOLAR wind, AURORAS, MAGNETIC fields

Abstract

This study presents a re‐evaluation of the Kullen and Janhunen (2004, https://doi.org/10.5194/angeo-22-951-2004) global northward interplanetary magnetic field (IMF) simulation, using the Grand Unified Magnetosphere–Ionosphere Coupling Simulation version 4 (GUMICS‐4), a global MHD model. We investigate the dynamic coupling between northward IMF conditions and the Earth's magnetotail and compare the results to observation‐based mechanisms for the formation of transpolar arcs. The results of this study reveal that under northward IMF conditions (and northward IMF initialization), a large closed field line region forms in the magnetotail, with similarities to transpolar arc structures observed from spacecraft data. This interpretation is supported by the simultaneous increase of closed flux measured in the magnetotail. However, the reconnection configuration differs in several respects from previously theorized magnetotail structures that have been inferred from both observations and simulations results and associated with transpolar arcs. We observe that dawn–dusk lobe regions form as a result of high‐latitude reconnection during the initialization stages, which later come into contact as the change in the IMF By component causes the magnetotail to twist. We conclude that in the GUMICS simulation, transpolar arc‐like structures are formed as a result of reconnection in the magnetotail, rather than high‐latitude reconnection or due to the mapping of the plasma sheet through a twisted magnetotail as interpreted from previous analysis of GUMICS simulations. Plain Language Summary: When the magnetic field associated with the solar wind is directed "northward," the Earth's aurora can adopt a formation where a "bar" of emission crosses the otherwise dim region that lies poleward of the usual auroral emissions. These phenomena are called "theta auroras" (due to their resemblance to the Greek letter), or "transpolar arcs," and have been observed from spacecraft observing the auroral regions. As spacecraft cannot directly observe the global configuration of magnetic field lines within planetary magnetospheres, simulations can be useful to gain insight into the possible structures that occur during different solar wind conditions. We use a global simulation to model the interaction between the solar wind and the Earth's magnetosphere (the region of space around our planet) and see that a large‐scale field line structure can form during certain northward‐directed magnetic field conditions. When we trace these field lines to the ionospheric boundary, we find that they resemble the global structures that have been observed for auroral arcs that stretch across the polar cap (also named theta aurora or transpolar arcs). We also note some key differences in their formation process from observational results. Key Points: Signatures consistent with magnetotail reconnection are observed in a simulation driven by northward interplanetary magnetic field conditionsThe simulation results in the production of a closed magnetotail structure and polar cap arcsThe above structure occurs within a magnetotail that is highly twisted such that open lobe regions cross the equatorial plane [ABSTRACT FROM AUTHOR]

Published

2023

5. Aurora in the Polar Cap: A Review.

Author

Hosokawa, Keisuke, Kullen, Anita, Milan, Steve, Reidy, Jade, Zou, Ying, Frey, Harald U., Maggiolo, Romain, and Fear, Robert

Abstract

This paper reviews our current understanding of auroral features that appear poleward of the main auroral oval within the polar cap, especially those that are known as Sun-aligned arcs, transpolar arcs, or theta auroras. They tend to appear predominantly during periods of quiet geomagnetic activity or northwards directed interplanetary magnetic field (IMF). We also introduce polar rain aurora which has been considered as a phenomenon on open field lines. We describe the morphology of such auroras, their development and dynamics in response to solar wind-magnetosphere coupling processes, and the models that have been developed to explain them. [ABSTRACT FROM AUTHOR]

Published

2020

6. Transpolar Arcs During a Prolonged Radial Interplanetary Magnetic Field Interval

Author

Park, Jong-Sun, Shi, Quan Qi, Nowada, Motoharu, Shue, Jih-Hong, Kim, Khan-Hyuk, Lee, Dong-Hun, Zong, Qiu-Gang, Degeling, Alexander W., Tian, An Min, Pitkänen, Timo, Zhang, Yongliang, Rae, I. Jonathan, Hairston, Marc R., Park, Jong-Sun, Shi, Quan Qi, Nowada, Motoharu, Shue, Jih-Hong, Kim, Khan-Hyuk, Lee, Dong-Hun, Zong, Qiu-Gang, Degeling, Alexander W., Tian, An Min, Pitkänen, Timo, Zhang, Yongliang, Rae, I. Jonathan, and Hairston, Marc R.

Abstract

Transpolar arcs (TPAs) are believed to predominantly occur under northward interplanetary magnetic field (IMF) conditions with their hemispheric asymmetry controlled by the Sun-Earth (radial) component of the IMF. In this study, we present observations of TPAs that appear in both the northern and southern hemispheres even during a prolonged interval of radially oriented IMF. The Defense Meteorological Satellite Program (DMSP) F16 and the Thermosphere Ionosphere Mesosphere Energetics and Dynamics (TIMED) satellites observed TPAs on the dawnside polar cap in both hemispheres (one TPA structure in the southern hemisphere and two in the northern hemisphere) during an interval of nearly earthward-oriented IMF on October 29, 2005. The southern hemisphere TPA and one of the northern hemisphere TPAs are associated with electron and ion precipitation and mostly sunward plasma flow (with shears) relative to their surroundings. Meanwhile, the other TPA in the northern hemisphere is associated with an electron-only precipitation and antisunward flow relative to its surroundings. Our observations indicate the following: (a) the TPA formation is not limited to northward IMF conditions; (b) the TPAs can be located on both closed field lines rooted in the polar cap of both hemispheres and open field lines connected to the northward field lines draped over one hemisphere of the magnetopause. We believe that the TPAs presented here are the result of both indirect and direct processes of solar wind energy transfer to the high-latitude ionosphere.

Published

2021

7. Transpolar arcs during a prolonged radial interplanetary magnetic field interval

Author

Park, J.-S. (Jong-Sun), Shi, Q. Q. (Quan Qi), Nowada, M. (Motoharu), Shue, J.-H. (Jih-Hong), Kim, K.-H. (Khan-Hyuk), Lee, D.-H. (Dong-Hun), Zong, Q.-G. (Qiu-Gang), Degeling, A. W. (Alexander W.), Tian, A. M. (An Min), Pitkänen, T. (Timo), Zhang, Y. (Yongliang), Rae, I. J. (I. Jonathan), Hairston, M. R. (Marc R.), Park, J.-S. (Jong-Sun), Shi, Q. Q. (Quan Qi), Nowada, M. (Motoharu), Shue, J.-H. (Jih-Hong), Kim, K.-H. (Khan-Hyuk), Lee, D.-H. (Dong-Hun), Zong, Q.-G. (Qiu-Gang), Degeling, A. W. (Alexander W.), Tian, A. M. (An Min), Pitkänen, T. (Timo), Zhang, Y. (Yongliang), Rae, I. J. (I. Jonathan), and Hairston, M. R. (Marc R.)

Abstract

Transpolar arcs (TPAs) are believed to predominantly occur under northward interplanetary magnetic field (IMF) conditions with their hemispheric asymmetry controlled by the Sun-Earth (radial) component of the IMF. In this study, we present observations of TPAs that appear in both the northern and southern hemispheres even during a prolonged interval of radially oriented IMF. The Defense Meteorological Satellite Program (DMSP) F16 and the Thermosphere Ionosphere Mesosphere Energetics and Dynamics (TIMED) satellites observed TPAs on the dawnside polar cap in both hemispheres (one TPA structure in the southern hemisphere and two in the northern hemisphere) during an interval of nearly earthward-oriented IMF on October 29, 2005. The southern hemisphere TPA and one of the northern hemisphere TPAs are associated with electron and ion precipitation and mostly sunward plasma flow (with shears) relative to their surroundings. Meanwhile, the other TPA in the northern hemisphere is associated with an electron-only precipitation and antisunward flow relative to its surroundings. Our observations indicate the following: (a) the TPA formation is not limited to northward IMF conditions; (b) the TPAs can be located on both closed field lines rooted in the polar cap of both hemispheres and open field lines connected to the northward field lines draped over one hemisphere of the magnetopause. We believe that the TPAs presented here are the result of both indirect and direct processes of solar wind energy transfer to the high-latitude ionosphere.

Published

2021

8. Simultaneous polar aurorae and modelled convection patterns in both hemispheres

Author

Cumnock, J.A., Blomberg, L.G., Alexeev, I.I., Belenkaya, E.S., Bobrovnikov, S.Yu., and Kalegaev, V.V.

Subjects

*CONVECTION (Meteorology), *INTERPLANETARY magnetic fields, *SOLAR wind, *AURORAL electrons

Abstract

Abstract: We present an event study illustrating the relationships between plasma convection and polar auroral emissions, as well as illustrating the influence of the interplanetary magnetic field’s y-component on theta aurora development in both hemispheres. Transpolar arcs (TPAs) are often observed during northward IMF with duskside (dawnside) formation of the TPA and dawnward (duskward) motion occurring when B y changes from positive to negative in the northern (southern) hemisphere. POLAR UVI provides images in the northern hemisphere while DMSP provides ionospheric plasma flow and precipitating particle data in both hemispheres. Concurrent solar wind plasma and interplanetary magnetic field measurements are provided by the ACE satellite. Utilizing the satellite data as inputs, the Royal Institute of Technology (KTH) numerical model provides the high-latitude ionospheric electrostatic potential patterns in both hemispheres calculated at different times during the evolution of the theta aurora resulting from a variety of field-aligned current configurations associated with the changing global aurora. These model patterns are compared to the convection predicted by mapping the magnetopause electric field to the ionosphere using the Moscow State University’s (MSU) paraboloid model of the magnetosphere. The model predicts that parallel electric fields are set up along the magnetic field lines projecting to the transpolar aurora. Their possible role in the acceleration of the auroral electrons is discussed. [Copyright &y& Elsevier]

Published

2006

9. The interaction between transpolar arcs and cusp spots

Author

Stephen E. Milan, J. A. Carter, Romain Maggiolo, and Robert Fear

Subjects

010504 meteorology & atmospheric sciences, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, Flux, Magnetosphere, Astrophysics, 01 natural sciences, Physics - Space Physics, 0103 physical sciences, medicine, Astrophysics::Solar and Stellar Astrophysics, Matematikk og Naturvitenskap: 400 [VDP], Interplanetary magnetic field, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Cusp spot, Cusp (singularity), Physics, Transpolar arc, Magnetic reconnection, Space Physics (physics.space-ph), Magnetic flux, Lobe, Geophysics, medicine.anatomical_structure, 13. Climate action, Lobe reconnection, Physics::Space Physics, General Earth and Planetary Sciences, Magnetopause

Abstract

Transpolar arcs and cusp spots are both auroral phenomena which occur when the interplanetary magnetic field is northward. Transpolar arcs are associated with magnetic reconnection in the magnetotail, which closes magnetic flux and results in a “wedge” of closed flux which remains trapped, embedded in the magnetotail lobe. The cusp spot is an indicator of lobe reconnection at the high-latitude magnetopause; in its simplest case, lobe reconnection redistributes open flux without resulting in any net change in the open flux content of the magnetosphere. We present observations of the two phenomena interacting—i.e., a transpolar arc intersecting a cusp spot during part of its lifetime. The significance of this observation is that lobe reconnection can have the effect of opening closed magnetotail flux. We argue that such events should not be rare. publishedVersion

Published

2015

10. Small-scale characteristics of extremely high latitude aurora

Author

Cumnock, Judy A., Blomberg, Lars G., Kullen, Anita, Karlsson, Tomas, Sundberg, K. Å. Torbjörn, Cumnock, Judy A., Blomberg, Lars G., Kullen, Anita, Karlsson, Tomas, and Sundberg, K. Å. Torbjörn

Abstract

We examine 14 cases of an interesting type of extremely high latitude aurora as identified in the precipitating particles measured by the DMSP F13 satellite. In particular we investigate structures within large-scale arcs for which the particle signatures are made up of a group of multiple distinct thin arcs. These cases are chosen without regard to IMF orientation and are part of a group of 87 events where DMSP F13 SSJ/4 measures emissions which occur near the noon-midnight meridian and are spatially separated from both the dawnside and duskside auroral ovals by wide regions with precipitating particles typical of the polar cap. For 73 of these events the high-latitude aurora consists of a continuous region of precipitating particles. We focus on the remaining 14 of these events where the particle signatures show multiple distinct thin arcs. These events occur during northward or weakly southward IMF conditions and follow a change in IMF B-y. Correlations are seen between the field-aligned currents and plasma flows associated with the arcs, implying local closure of the FACs. Strong correlations are seen only in the sunlit hemisphere. The convection associated with the multiple thin arcs is localized and has little influence on the large-scale convection. This also implies that the sunward flow along the arcs is unrelated to the overall ionospheric convection., QC 20100525

Published

2009

11. Polar auroral arcs

Author

Kullen, Anita

Subjects

polar arc, solar wind-magnetosphere coupling, interplanetary magnetic field, transpolar arc

Abstract

NR 20140805

Published

2003

12. Simultaneous polar aurorae and modelled convection patterns in both hemispheres

Author

Cumnock, Judy A., Blomberg, Lars G., Alexeev, I. I., Belenkaya, E. S., Bobrovnikov, S. Yu., Kalegaev, V. V., Cumnock, Judy A., Blomberg, Lars G., Alexeev, I. I., Belenkaya, E. S., Bobrovnikov, S. Yu., and Kalegaev, V. V.

Abstract

We present an event study illustrating the relationships between plasma convection and polar auroral emissions, as well as illustrating the influence of the interplanetary magnetic field's y-component on theta aurora development in both hemispheres. Transpolar arcs (TPAs) are often observed during northward IMF with duskside (dawnside) formation of the TPA and dawnward (duskward) motion occurring when B-y changes from positive to negative in the northern (southern) hemisphere. POLAR UVI provides images in the northern hemisphere while DMSP provides ionospheric plasma flow and precipitating particle data in both hemispheres. Concurrent solar wind plasma and interplanetary magnetic field measurements are provided by the ACE satellite. Utilizing the satellite data as inputs, the Royal Institute of Technology (KTH) numerical model provides the high-latitude ionospheric electrostatic potential patterns in both hemispheres calculated at different times during the evolution of the theta aurora resulting from a variety of field-aligned current configurations associated with the changing global aurora. These model patterns are compared to the convection predicted by mapping the magnetopause electric field to the ionosphere using the Moscow State University's (MSU) paraboloid model of the magnetosphere. The model predicts that parallel electric fields are set up along the magnetic field lines projecting to the transpolar aurora. Their possible role in the acceleration of the auroral electrons is discussed., QC 20160721

Published

2006

13. POLAR UVI Observations of Auroral Oval Intensifications During a Transpolar Arc Event on December 7, 1996

Author

Cumnock, Judy, Spann, J. F., Germany, G. A., Blomberg, Lars, Coley, W. R., Clauer, C. R., and Brittnacher, M. J.

Subjects

Theta Aurora, Fusion, plasma och rymdfysik, Transpolar Arc, Substorm, Northward IMF, Auroral Physics, Magnetosphere-ionosphere Coupling, Fusion, Plasma and Space Physics

Abstract

The evolution of the northern hemisphere aurora is examined during a time when the IMF makes three brief southward excursions after a change in the sign of By during an extended period of northward IMF. POLAR UVI provides images of the aurora while DMSP F13 and F14 provide in situ measurements of precipitating particles, ionospheric plasma flows and ion density. Three different intensifications located in the nightside auroral oval occur during northward turnings of the IMF after brief periods of southward IMF. Spatial expansion, intensity of emissions and their duration are related to the length of time the IMF is southward prior to the northward turning. Thus the longer the period of enhanced magnetospheric convection the more intense the ionospheric response. Observations of a transpolar arc indicate that when the transpolar arc reaches highest latitudes it is located on a spatially narrow region of closed field lines, which extends along the noon-midnight meridian. UV observations indicate a connection between the transpolar arc and the nightside auroral enhancements. Precipitating particles associated with both features are attributed to a plasma sheet boundary layer source in the magnetotail implying a magnetospheric connection between the transpolar arc and the nightside auroral oval intensification. QC 20120530

Published

2000

14. Solar wind dependence of the occurrence and motion of polar auroral arcs : A statistical study

Author

Kullen, A., Brittnacher, M., Cumnock, J. A., Blomberg, Lars G., Kullen, A., Brittnacher, M., Cumnock, J. A., and Blomberg, Lars G.

Abstract

[1] Polar UV images from a 3-month period in winter 1998-1999 are used for a statistical study of polar arcs. The study covers all auroral arcs that are located poleward of the northern auroral oval, and which are detectable by the UV imager. The arcs are examined with respect to their spatial and temporal behavior as well as to a possible connection to solar wind parameters using ACE satellite data. It is found that the majority of polar arcs appear during northward IMF, strong IMF magnitude, and high solar wind speed. A modified Akasofu-Perreault epsilon parameter with a cosine function instead of a sine function (nuB(2) cos(4) (theta/2)(l(0)(2)/mu(0))) combines these results. It correlates well with the occurrence frequency of polar arcs for long timescales. The location of polar arcs is strongly dependent on the sign of the IMF B-y component. Static polar arcs occur in the Northern Hemisphere on the dawn (dusk) side of the oval for negative (positive) IMF B-y, whereas poleward-moving arcs separate from the opposite side of the oval, and then move in the direction of IMF B-y. All polar arcs are sorted into five different categories according to their spatial structure and evolution: oval-aligned, bending, moving, midnight, and multiple arcs. Each polar arc type occurs for a characteristic combination of solar wind parameters. IMF clock angle changes seem to have a strong influence on what type of arc occurs. Oval-aligned arcs appear mainly during steady IMF, bending arcs after an IMF B-z sign change, and moving arcs after an IMF B-y sign change. For the rare midnight and multiple arc events, no characteristic IMF clock angle dependence has been found. The different types of clear polar arcs are discussed in the context of existing observational studies and transpolar arc models., QC 20100525 NR 20140804

Published

2002