Applying Magnetic Curvature to MMS Data to Identify Thin Current Sheets Relative to Tail Reconnection

Rogers, A. J.; Farrugia, Charles J.; Torbert, R. B.; Rogers, Timothy

doi:10.1029/2022ja030577

Cited by 11 publications

(16 citation statements)

References 55 publications

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“…A recent systematic survey of MMS plasma and field data in 2017 (Rogers et al, 2019) identified 12 such magnetotail IDRs, defined as correlated reversals of the proton bulk flow velocity, v x , and the North-South magnetic field, B z , as shown in Figure 1 inset, along with additional Hall magnetic and electric field signatures. That analysis was later extended to 2018-2020 for a total of 26 IDR events (Rogers et al, 2023) labeled here A-Z, "IDR alphabet", listed in Table 2. The second column in the table lists the starting date and time of each IDR interval found in Rogers et al (2023).…”

Section: Reconnection Features In the Equatorial Planementioning

confidence: 99%

“…That analysis was later extended to 2018-2020 for a total of 26 IDR events (Rogers et al, 2023) labeled here A-Z, "IDR alphabet", listed in Table 2. The second column in the table lists the starting date and time of each IDR interval found in Rogers et al (2023). Due to the 5 min cadence of our DM approach, the actual reconstructed times are rounded to the nearest 5 min as indicated in the third column.…”

Section: Reconnection Features In the Equatorial Planementioning

confidence: 99%

“…The second column in the table lists the starting date and time of each IDR interval found in Rogers et al. (2023). Due to the 5 min cadence of our DM approach, the actual reconstructed times are rounded to the nearest 5 min as indicated in the third column.…”

Section: Idrs and Reconstructed Global Reconnection Structuresmentioning

confidence: 99%

“…The recent four‐probe Magnetospheric MultiScale (MMS) mission (Burch, Moore, et al., 2016) enabled microscopic analysis of magnetotail reconnection down to electron gyroradius scales (Torbert et al., 2018). During 4 yr of MMS observations, 26 potential X‐line encounters were found in the magnetotail (Rogers et al., 2019, 2023), where explosive reconnection causes substorms (Angelopoulos et al., 2020, 2008; Sitnov, Stephens, et al., 2019). They were detected in the form of Ion Diffusion Regions (IDRs) characterized by reversals of the North‐South component of the magnetic field, B z , and of the Sun‐Earth component of the proton bulk flow velocity, v x .…”

Section: Introductionmentioning

confidence: 99%

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Global Structure of Magnetotail Reconnection Revealed by Mining Space Magnetometer Data

et al. 2023

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X-lines are one of the most fundamental structures in magnetized plasmas, particularly in space, where they link global or even astronomical scale processes to those on the single particle orbit scale, thereby allowing those microscale processes to shape the universe (Ji et al., 2022). Dungey (1961) suggested that the interaction between Earth's magnetic dipole and the solar wind causes reconnection of magnetic field lines on both the day and nightsides of Earth's magnetosphere. The shape of these reconnecting field lines resembles the letter "X" and extends tens of Earth radii (R E = 6,371.2 km) in the dawn-dusk direction thus forming X-lines. An X-line divides space into four sectors. In one pair of opposing sectors, the magnetic field and plasma converge toward the center of the X while in the other pair, they are rapidly ejected from it. This reconnection process transforms energy stored in the magnetic field into particle kinetic and thermal energy, making it an efficient energy converter and particle accelerator (Ji et al., 2022). X-lines couple kinetic processes on proton and even electron gyroradius scales (≲0.01R E ) (Torbert et al., 2018) to space weather phenomena on global scales: such as solar flares, coronal mass ejections, and magnetospheric storms and substorms (∼10R E ) (Camporeale, 2019). This range of scales is so immense that its modeling has become one of the major challenges for nascent exascale computing (Ji et al., 2022).

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Section: Reconnection Features In the Equatorial Planementioning

confidence: 99%

Section: Reconnection Features In the Equatorial Planementioning

confidence: 99%

Section: Idrs and Reconstructed Global Reconnection Structuresmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Global Structure of Magnetotail Reconnection Revealed by Mining Space Magnetometer Data

et al. 2023

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“…7 in Tsyganenko (1998)). Thin current sheets are more commonly found from midnight to dusk (Rogers et al., 2023). The anti‐parallel field configuration and low collisionality make it an ideal system to apply the theory.…”

Section: Applicationsmentioning

confidence: 99%

Three‐Dimensional Magnetic Reconnection Spreading in Current Sheets of Non‐Uniform Thickness

et al. 2023

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The abrupt release of magnetic energy in substorms in Earth's magnetosphere and flares in the solar corona are key features of the dynamics of these systems and have an important impact on Earth's technological infrastructure. In both processes, magnetic reconnection is the driver of the rapid energy conversion (McPherron et al., 1973;Priest & Forbes, 2000) via a change in magnetic field connectivity (Dungey, 1953;Vasyliunas, 1975). Observations have revealed that reconnecting x-lines (the collection of points where the magnetic field connectivity changes) often start in a localized region of space, and then elongate or spread in time, orthogonal to the reconnection plane in two-ribbon solar flares (

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Global-Scale Processes and Effects of Magnetic Reconnection on the Geospace Environment

Fuselier,

Petrinec,

Reiff

et al. 2024

Space Sci Rev

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Recent multi-point measurements, in particular from the Magnetospheric Multiscale (MMS) spacecraft, have advanced the understanding of micro-scale aspects of magnetic reconnection. In addition, the MMS mission, as part of the Heliospheric System Observatory, combined with recent advances in global magnetospheric modeling, have furthered the understanding of meso- and global-scale structure and consequences of reconnection. Magnetic reconnection at the dayside magnetopause and in the magnetotail are the drivers of the global Dungey cycle, a classical picture of global magnetospheric circulation. Some recent advances in the global structure and consequences of reconnection that are addressed here include a detailed understanding of the location and steadiness of reconnection at the dayside magnetopause, the importance of multiple plasma sources in the global circulation, and reconnection consequences in the magnetotail. These advances notwithstanding, there are important questions about global reconnection that remain. These questions focus on how multiple reconnection and reconnection variability fit into and complicate the Dungey Cycle picture of global magnetospheric circulation.

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Applying Magnetic Curvature to MMS Data to Identify Thin Current Sheets Relative to Tail Reconnection

Cited by 11 publications

References 55 publications

Global Structure of Magnetotail Reconnection Revealed by Mining Space Magnetometer Data

Global Structure of Magnetotail Reconnection Revealed by Mining Space Magnetometer Data

Three‐Dimensional Magnetic Reconnection Spreading in Current Sheets of Non‐Uniform Thickness

Global-Scale Processes and Effects of Magnetic Reconnection on the Geospace Environment

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