Search

Your search keyword '"Phan, Tai D."' showing total 39 results
Start Over Author "Phan, Tai D."
39 results on '"Phan, Tai D."'

1. Out-of-plane Parallel Current in the Diffusion Regions: The Interaction Between Diffusion Region Systems and their Impact on the Outer EDR

Author

Beedle, Jason M. H., Gershman, Daniel J., Uritsky, Vadim M., Shuster, Jason R., Phan, Tai D., Giles, Barbara L., Genestreti, Kevin J., and Torbert, Roy B.

Subjects
Physics - Space Physics
Abstract

Dayside magnetic reconnection allows for the transfer of the solar wind's energy into Earth's magnetosphere. This process takes place in electron diffusion regions (EDRs) embedded in ion diffusion regions (IDRs), which form in the magnetopause boundary's current sheet. A significant out-of-plane parallel current contribution in the diffusion regions was reported in Beedle et al. 2023. In order to understand the underlying structure of this parallel current, we compared EDR statistical results with a 2.5D Particle-In Cell (PIC) simulation. From this comparison, we identified out-of-plane parallel current signatures as defining features of the outer EDR and IDR. This significant out-of-plane parallel current indicates the interaction of the IDR and EDR systems, and provides implications for not only understanding energy dissipation in the diffusion regions, but also determining the location of the outer EDR.

Published
2024

2. Differentiating EDRs from the Background Magnetopause Current Sheet: A Statistical Study

Author

Beedle, Jason M. H., Gershman, Daniel J., Uritsky, Vadim M., Phan, Tai D., and Giles, Barbara L.

Subjects
Physics - Space Physics
Abstract

The solar wind is a continuous outflow of charged particles from the Sun's atmosphere into the solar system. At Earth, the solar wind's outward pressure is balanced by the Earth's magnetic field in a boundary layer known as the magnetopause. Plasma density and temperature differences across the boundary layer generate the Chapman-Ferraro current which supports the magnetopause. Along the dayside magnetopause, magnetic reconnection can occur in electron diffusion regions (EDRs) embedded into the larger ion diffusion regions (IDRs). These diffusion regions form when opposing magnetic field lines in the solar wind and Earth's magnetic field merge, releasing magnetic energy into the surrounding plasma. While previous studies have given us a general understanding of the structure of the diffusion regions, we still do not have a good grasp of how they are statistically differentiated from the non-diffusion region magnetopause. By investigating 251 magnetopause crossings from NASA's Magnetospheric Multiscale (MMS) Mission, we demonstrate that EDR magnetopause crossings show current densities an order of magnitude higher than regular magnetopause crossings - crossings that either passed through the reconnection exhausts or through the non-reconnecting magnetopause, providing a baseline for the magnetopause current sheet under a wide range of driving conditions. Significant current signatures parallel to the local magnetic field in EDR crossings are also identified, which is in contrast to the dominantly perpendicular current found in the regular magnetopause. Additionally, we show that the ion velocity along the magnetopause is highly correlated with a crossing's location, indicating the presence of magnetosheath flows inside the magnetopause.

Published
2023

3. A Systematic Look at the Temperature Gradient Contribution to the Dayside Magnetopause Current

Author

Beedle, Jason M. H., Gershman, David J., Uritsky, Vadim M., Phan, Tai D., and Giles, Barbara L.

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

Magnetopause diamagnetic currents arise from density and temperature driven pressure gradients across the boundary layer. While theoretically recognized, the temperature contributions to the magnetopause current system have not yet been systematically studied. To bridge this gap, we used a database of Magnetospheric Multiscale (MMS) magnetopause crossings to analyze diamagnetic current densities and their contributions across the dayside and flank magnetopause. Our results indicate that the ion temperature gradient component makes up to 37% of the ion diamagnetic current density along the magnetopause and typically opposes the classical Chapman-Ferraro current direction, interfering destructively with the density gradient component, thus lowering the total diamagnetic current density. This effect is most pronounced on the flank magnetopause. The electron diamagnetic current was found to be 5 to 14 times weaker than the ion diamagnetic current on average.

Published
2021
Full Text
View/download PDF

5. The Reduction of Magnetic Reconnection Outflow Jets to Sub-Alfv\'enic Speeds

Author

Haggerty, Colby C., Shay, Michael A., Chasapis, Alexandros, Phan, Tai D., Drake, James F., Malakit, Kittipat, Cassak, Paul A., and Kieokaew, Rungployphan

Subjects
Physics - Plasma Physics
Abstract

The outflow velocity of jets produced by collisionless magnetic reconnection is shown to be reduced by the ion exhaust temperature in simulations and observations. We derive a scaling relationship for the outflow velocity based on the upstream Alfv\'en speed and the parallel ion exhaust temperature, which is verified in kinetic simulations and observations. The outflow speed reduction is shown to be due to the firehose instability criterion, and so for large enough guide fields this effect is suppressed and the outflow speed reaches the upstream Alfv\'en speed based on the reconnecting component of the magnetic field.

Published
2018
Full Text
View/download PDF

6. MMS observation of asymmetric reconnection supported by 3-D electron pressure divergence

Author

Genestreti, Kevin J., Varsani, Ali, Burch, Jim L., Cassak, Paul A., Torbert, Roy B., Nakamura, Rumi, Ergun, Robert E., Phan, Tai D., Toledo-Redondo, Sergio, Hesse, Michael, Wang, Shan, Giles, Barbara L., Russell, Chris T., Vörös, Zoltan, Kim, Kyoung-Joo, Eastwood, Jonathan P., Lavraud, Benoit, Escoubet, C. Philippe, Fear, Robert C., Khotyaintsev, Yuri, Nakamura, Takuma, Webster, James M., and Baumjohann, Wolfgang

Subjects
Physics - Space Physics
Abstract

We identify a dayside electron diffusion region (EDR) encountered by the Magnetospheric Multiscale (MMS) mission and estimate the terms in generalized Ohm's law that controlled energy conversion near the X-point. MMS crossed the moderate-shear (130 degrees) magnetopause southward of the exact X-point. MMS likely entered the magnetopause far from the X-point, outside the EDR, as the size of the reconnection layer was less than but comparable to the magnetosheath proton gyro-radius, and also as anisotropic gyrotropic "outflow" crescent electron distributions were observed. MMS then approached the X-point, where all four spacecraft simultaneously observed signatures of the EDR, e.g., an intense out-of-plane electron current, moderate electron agyrotropy, intense electron anisotropy, non-ideal electric fields, non-ideal energy conversion, etc. We find that the electric field associated with the non-ideal energy conversion is (a) well described by the sum of the electron inertial and pressure divergence terms in generalized Ohms law though (b) the pressure divergence term dominates the inertial term by roughly a factor of 5:1, (c) both the gyrotropic and agyrotropic pressure forces contribute to energy conversion at the X-point, and (d) both out-of-the-reconnection-plane gradients (d/dM) and in-plane (d/dL,N) in the pressure tensor contribute to energy conversion near the X-point. This indicates that this EDR had some electron-scale structure in the out-of-plane direction during the time when (and at the location where) the reconnection site was observed., Comment: Submitted to JGR Space Physics (November 2017), resubmitted after 1st round of minor revisions (January 2018)

Published
2017
Full Text
View/download PDF

7. Statistical Study of Energy Transport and Conversion in Electron Diffusion Regions at Earth's Dayside Magnetopause.

Author

Fargette, Naïs, Eastwood, Jonathan P., Waters, Cara L., Øieroset, Marit, Phan, Tai D., Newman, David L., Stawarz, J. E., Goldman, Martin V., and Lapenta, Giovanni

Subjects
MAGNETIC reconnection, EARTH (Planet), ENERGY conversion, ELECTRON density, MAGNETOPAUSE
Abstract

The electron diffusion region (EDR) is a key region for magnetic reconnection, but the typical energy transport and conversion in EDRs is still not well understood. In this work, we perform a statistical study of 80 previously published near X‐line events identified at the dayside magnetopause in Magnetospheric Multiscale data. We find 44 events that clearly present all commonly accepted EDR signatures and use this database to investigate energy flux partition and energy conversion. We find that energy partition is changed inside EDRs, with a 71%–29% allocation of particle energy flux density between electrons and ions respectively. The electron enthalpy flux density is found to dominate locally at all EDRs and is predominantly oriented in the out‐of‐plane direction, perpendicular to the reconnecting magnetic field. We also examine the transition from electron‐ to ion‐dominated energy flux partition further from the EDR, finding this typically occurs at scales of the order of the ion inertial length, larger than the typical EDR size. We then investigate energy conversion and transport and highlight complex processes, with potential non‐steady‐state energy accumulation and release near the EDR. We discuss the implications of our results for reconnection energy conversion, and for magnetopause dynamics in general. Plain Language Summary: Magnetic reconnection is a key plasma phenomenon that occurs in many astrophysical systems, such as in the atmosphere of stars and in the vicinity of magnetized planets like the Earth. It enables rapid conversion of energy as particles gain energy from the magnetic field and are accelerated and heated. In 2015, the 4‐satellite Magnetospheric Multi‐Scale (MMS) mission launched to specifically probe magnetic reconnection close to the Earth. Here we analyze MMS data, first reviewing all previously reported measurements of the very heart of the reconnection region by MMS, and cross‐analyzing them to provide a catalog of 44 confirmed events. We use this catalog to understand how energy is changing during reconnection, finding that energy is mostly deposited to electrons at the heart of the reconnection region. The transport of thermal energy is most important there, and this energy is flowing out of the reconnection region in a direction transverse to the magnetic field. We find that the transfer of energy between field and particles is complex, with temporal effects at play near the reconnection region. These findings bring new insight into the physics of reconnection energetics and have wide implications for wherever reconnection is observed. Key Points: We provide the first comparative statistical study of all previously reported MMS dayside magnetopause EDRs and confirm 44 clear encountersEnergy flux partition changes at the EDR, it is locally dominated by the electron enthalpy flux oriented in the out‐of‐plane directionWe highlight complex field‐particle energy exchange near the EDR where temporal and non linear effects seem play a role [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

8. Investigation of a Magnetic Reconnection Event with Extraordinarily High Particle Energization in Magnetotail Turbulence

Author

Qi, Yi, primary, Ergun, Robert, additional, Pathak, Neha, additional, Phan, Tai D., additional, Burch, James L., additional, Chasapis, Alexandros, additional, Li, Tak Chu, additional, Schwartz, Steven J., additional, Ahmadi, Narges, additional, Vo, Tien, additional, Eriksson, Stefan, additional, Newman, David, additional, Usanova, Maria, additional, and Wilder, Frederick D., additional

Published
2024
Full Text
View/download PDF

10. Clustering of magnetic reconnection exhausts in the solar wind: An automated detection study

Author

Fargette, Naïs, primary, Lavraud, Benoît, additional, Rouillard, Alexis P., additional, Houdayer, Pierre S., additional, Phan, Tai D., additional, Øieroset, Marit, additional, Eastwood, Jonathan P., additional, Nicolaou, Georgios, additional, Fedorov, Andrei, additional, Louarn, Philippe, additional, Owen, Christopher J., additional, and Horbury, Tim S., additional

Published
2023
Full Text
View/download PDF

11. Magnetic Reconnection as the Driver of the Solar Wind

Author

Raouafi, Nour E., primary, Stenborg, Guillermo, additional, Seaton, Dan B., additional, Wang, Haimin, additional, Wang, Jason, additional, DeForest, Craig E., additional, Bale, Stuart D., additional, Drake, James F., additional, Uritsky, Vadim M., additional, Karpen, Judith T., additional, DeVore, Carl R., additional, Sterling, Alphonse C., additional, Horbury, Timothy S., additional, Harra, Louise K., additional, Bourouaine, Sofiane, additional, Kasper, Justin C., additional, Kumar, Pankaj, additional, Phan, Tai D., additional, and Velli, Marco, additional

Published
2023
Full Text
View/download PDF

12. Magnetic Reconnection as the Driver of the Solar Wind

Author

Raouafi, Nour E., Stenborg, Guillermo, Seaton, Daniel B., Wang, Haimin, Wang, Jiasheng, DeForest, Craig E., Bale, Stuart D., Drake, James F., Uritsky, Vadim M., DeVore, Carl R., Sterling, Alphonse C., Horbury, Timothy S., Harra, Louise, Bourouaine, Sofiane, Kasper, Justin C., Kumar, Pankaj, Phan, Tai D., and Velli, Marco

Abstract

We present EUV solar observations showing evidence for omnipresent jetting activity driven by small-scale magnetic reconnection at the base of the solar corona. We argue that the physical mechanism that heats and drives the solar wind at its source is ubiquitous magnetic reconnection in the form of small-scale jetting activity (a.k.a. jetlets). This jetting activity, like the solar wind and the heating of the coronal plasma, is ubiquitous regardless of the solar cycle phase. Each event arises from small-scale reconnection of opposite-polarity magnetic fields producing a short-lived jet of hot plasma and Alfvén waves into the corona. The discrete nature of these jetlet events leads to intermittent outflows from the corona, which homogenize as they propagate away from the Sun and form the solar wind. This discovery establishes the importance of small-scale magnetic reconnection in solar and stellar atmospheres in understanding ubiquitous phenomena such as coronal heating and solar wind acceleration. Based on previous analyses linking the switchbacks to the magnetic network, we also argue that these new observations might provide the link between the magnetic activity at the base of the corona and the switchback solar wind phenomenon. These new observations need to be put in the bigger picture of the role of magnetic reconnection and the diverse form of jetting in the solar atmosphere., The Astrophysical Journal, 945 (1), ISSN:0004-637X, ISSN:2041-8213

Published
2023
Full Text
View/download PDF

15. Asymmetric Interaction of a Solar Wind Reconnecting Current Sheet and Its Magnetic Hole With Earth's Bow Shock and Magnetopause

Author

Madanian, Hadi, Liu, Terry Z., Phan, Tai D., Trattner, Karlheinz J., Karlsson, Tomas, Liemohn, Michael W., Madanian, Hadi, Liu, Terry Z., Phan, Tai D., Trattner, Karlheinz J., Karlsson, Tomas, and Liemohn, Michael W.

Abstract

We report results of our multi-spacecraft analysis of a solar wind reconnecting current sheet (RCS) and its solar wind magnetic hole (SWMH) observed on November 20, 2018. In the solar wind, the normal vector to the current sheet plane makes an angle of 32 degrees with the Sun-Earth line. A combination of tilted current sheet plane and foreshock effects cause an asymmetric interaction with the bow shock, in which the structure arrives at the quasi-perpendicular side of the bow shock before the quasi-parallel side. The magnetic field strength inside the magnetic hole decreases by similar to 69 percent in the solar wind, with a similar depression rate observed inside the magnetosheath due to this structure. The solar wind flow slowdown and deflection during the bow shock crossing significantly disrupt the reconnection exhausts within the RCS. The interaction of the RCS and SWMH with the bow shock creates enhanced fluxes of accelerated electrons and ions. Plasma flow deflection in the magnetosheath also increases with the passage of the RCS. The ion density and temperature both increase within the current sheet to form a roughly pressure balanced structure. Field rotation and change in the dynamic pressure during this event modify the reconnection zones at the magnetopause and cause asymmetric inward motions in portions of the bow shock and the magnetopause boundaries (i.e., deformation). Unlike localized magnetosheath jets, an RCS and its associated SWMH in the solar wind have a global impact on the bow shock and the magnetopause., QC 20220516

Published
2022
Full Text
View/download PDF

17. Magnetic Field Annihilation in a Magnetotail Electron Diffusion Region with Electron-scale Magnetic Island

Author

Hasegawa, Hiroshi, primary, Denton, Richard E., additional, Nakamura, Takuma, additional, Genestreti, Kevin J, additional, Phan, Tai D, additional, Nakamura, Rumi, additional, Hwang, Kyoung-Joo, additional, Ahmadi, Narges, additional, Shi, Quanqi, additional, Hesse, Michael, additional, Burch, James L, additional, Webster, James Matthew, additional, Torbert, Roy B., additional, Giles, Barbara L., additional, Gershman, Daniel J, additional, Russell, Christopher T., additional, Strangeway, Robert J., additional, Wei, H. Y., additional, Lindqvist, Per-Arne, additional, Khotyaintsev, Yuri V., additional, Ergun, Robert E, additional, and Saito, Yoshifumi, additional

Published
2022
Full Text
View/download PDF

19. Characteristic Scales of Magnetic Switchback Patches Near the Sun and Their Possible Association With Solar Supergranulation and Granulation

Author

Fargette, Naïs, primary, Lavraud, Benoit, additional, Rouillard, Alexis P., additional, Réville, Victor, additional, Dudok De Wit, Thierry, additional, Froment, Clara, additional, Halekas, Jasper S., additional, Phan, Tai D., additional, Malaspina, David M., additional, Bale, Stuart D., additional, Kasper, Justin C., additional, Louarn, Philippe, additional, Case, Anthony W., additional, Korreck, Kelly E., additional, Larson, Davin E., additional, Pulupa, Marc, additional, Stevens, Michael L., additional, Whittlesey, Phyllis L., additional, and Berthomier, Matthieu, additional

Published
2021
Full Text
View/download PDF

23. MMS observation of asymmetric reconnection supported by 3-D electron pressure divergence

Author

Genestreti, Kevin J., Varsani, Ali, Burch, Jim L., Cassak, Paul A., Torbert, Roy B., Nakamura, Rumi, Ergun, Robert E., Phan, Tai D., Toledo-Redondo, Sergio, Hesse, Michael, Wang, Shan, Giles, Barbara L., Russell, Chris T., Vörös, Zoltan, Kim, Kyoung-Joo, Eastwood, Jonathan P., Lavraud, Benoit, Escoubet, C. Philippe, Fear, Robert C., Khotyaintsev, Yuri, Nakamura, Takuma, Webster, James M., Baumjohann, Wolfgang, and Science and Technology Facilities Council (STFC)

Subjects
Science & Technology, WAVES, FOS: Physical sciences, Astronomy & Astrophysics, X LINE, Space Physics (physics.space-ph), DRIFT, Physics - Space Physics, MAGNETIC RECONNECTION, MAGNETOPAUSE RECONNECTION, Physics::Space Physics, Physical Sciences, DIFFUSION REGION, TURBULENCE, PARALLEL, FIELD, MAGNETOSPHERIC MULTISCALE OBSERVATIONS
Abstract

We identify a dayside electron diffusion region (EDR) encountered by the Magnetospheric Multiscale (MMS) mission and estimate the terms in generalized Ohm's law that controlled energy conversion near the X-point. MMS crossed the moderate-shear (130 degrees) magnetopause southward of the exact X-point. MMS likely entered the magnetopause far from the X-point, outside the EDR, as the size of the reconnection layer was less than but comparable to the magnetosheath proton gyro-radius, and also as anisotropic gyrotropic "outflow" crescent electron distributions were observed. MMS then approached the X-point, where all four spacecraft simultaneously observed signatures of the EDR, e.g., an intense out-of-plane electron current, moderate electron agyrotropy, intense electron anisotropy, non-ideal electric fields, non-ideal energy conversion, etc. We find that the electric field associated with the non-ideal energy conversion is (a) well described by the sum of the electron inertial and pressure divergence terms in generalized Ohms law though (b) the pressure divergence term dominates the inertial term by roughly a factor of 5:1, (c) both the gyrotropic and agyrotropic pressure forces contribute to energy conversion at the X-point, and (d) both out-of-the-reconnection-plane gradients (d/dM) and in-plane (d/dL,N) in the pressure tensor contribute to energy conversion near the X-point. This indicates that this EDR had some electron-scale structure in the out-of-plane direction during the time when (and at the location where) the reconnection site was observed., Comment: Submitted to JGR Space Physics (November 2017), resubmitted after 1st round of minor revisions (January 2018)

Published
2018

26. Parallel electron heating in the magnetospheric inflow region

Author

Wang, Shan, primary, Chen, Li‐Jen, additional, Hesse, Michael, additional, Wilson, Lynn B., additional, Bessho, Naoki, additional, Gershman, Daniel J., additional, Ergun, Robert E., additional, Phan, Tai D., additional, Burch, James L., additional, Dorelli, John C., additional, Giles, Barbara, additional, Torbert, Roy B., additional, Pollock, Craig J., additional, Russell, Christopher T., additional, Strangeway, Robert, additional, Avanov, Levon, additional, Lavraud, Benoit, additional, and Moore, Thomas E., additional

Published
2017
Full Text
View/download PDF

27. Can magnetotail reconnection produce the auroral intensities observed in the conjugate ionosphere?

Author

Østgaard, Nikolai, Snekvik, Kristian, Borg, Anette Lauen, Åsnes, Arne, Pedersen, Arne, Øieroset, Marit, Phan, Tai D., and Haaland, Stein

Subjects
Physics::Plasma Physics, Mathematics and natural scienses: 400::Physics: 430::Space and plasma physics: 437 [VDP], Physics::Space Physics, Matematikk og naturvitenskap: 400::Fysikk: 430::Rom- og plasmafysikk: 437 [VDP]
Abstract

[1] In a recent case study, Borg et al. (2007) reported that an inverted V structure, caused by a field-aligned potential drop of 30 kV producing very strong X-ray aurora, was found in connection with tail reconnection. However, the in situ particle measurements indicated clearly that the particles responsible for the X-ray aurora were not accelerated by the reconnection process. In this article, we report the predicted auroral intensities of thirteen reconnection events where Cluster passed through the reconnection region. For six of the events, global auroral imaging data were available and the predicted auroral intensities could be compared with the observed intensities. Our main findings are as follows: (1) Acceleration in the reconnection region is generally not sufficient to account for the observed auroral intensities. (2) Additional acceleration between the reconnection region and the ionosphere is needed to explain the auroral intensities. Although we see signatures that point toward potential drops at the flanks of bursty bulk flows (BBFs), we also find signatures of Alfvén wave accelerated electrons at 700 km and we are not able to determine the most likely acceleration mechanism. (3) The reconnection events are observed 2–14 min after substorm onset and indicate that reconnection is an expanding process observed along the poleward boundary of the aurora. publishedVersion

Published
2009

Catalog

Books, media, physical & digital resources
See catalog results