Magnetic Reconnection in the Space Sciences: Past, Present, and Future

Hesse, Michael; Cassak, P. A.

doi:10.1029/2018ja025935

Cited by 111 publications

(78 citation statements)

References 106 publications

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“…where sunspot area max ≈ 7.5 • 10 9 km 2 ≈ 2470 ppm, sunspot area min ≈ 9.0 • 10 8 km 2 ≈ 300 ppm of visible hemisphere is the sunspot area (over the visible hemisphere [123,124]) for the cycle 22 experimentally observed by the Japanese X-ray telescope Yohkoh (1991) (see [96]); R Sun = 6.96 × 10 5 km; P a→γ ≈ 1 at maximum of solar luminosity, and P a→γ ≈ 0.95 at minimum (see Eqs. (119) and (120) in [8]). The product of the total fraction of axions originating from the Sun core and the fraction of the sunspot area (see [123,124]) yields the total fraction of the corona luminosity, or more precisely, the fraction of photon luminosity of axion origin in the corona.…”

Section: Solving the Problem Of Corona Temperaturementioning

confidence: 99%

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Coronal heating problem solution by means of axion origin photons

Rusov

Sharph

Smolyar

et al. 2021

Physics of the Dark Universe

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In this paper we advocate for the idea that two seemingly unrelated mysteries with almost 90 year history-the nature of dark matter and the million-degree solar corona-may be but two sides of the same coin-the axions of dark matter born in the core of the Sun and photons of axion origin in the million-degree solar corona, whose modulations are controlled by the anticorrelated modulation of the asymmetric dark matter (ADM) density in the solar interior.

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Section: Solving the Problem Of Corona Temperaturementioning

confidence: 99%

“…Let us recall the jocular but practically understandable words of M. Hesse and P. A. Cassak[120] about the essence of magnetic reconnection: "There is an imprecise -but useful -analogy to rubber bands that helps us picture magnetic reconnection. A loose rubber band cannot hold a pile of pencils in place, but a stretched rubber band can.…”

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confidence: 99%

Coronal heating problem solution by means of axion origin photons

Rusov

Sharph

Smolyar

et al. 2021

Physics of the Dark Universe

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“…It can further address the critical question of why reconnection operates in small bursts at times and in large eruptions at others. It will furthermore shed light on the puzzle of whether large eruptions are a collection of small bursts occurring together, or whether they are a different, organized, type of reconnection altogether [11]. Understanding when and how these disruptions occur is also critical to predict the harmful effects on the space environment, which are collectively referred to as "space weather" [12].…”

Section: Scientific Rationale For Cross-scale Constellation Missionsmentioning

confidence: 99%

AME: A Cross-Scale Constellation of CubeSats to Explore Magnetic Reconnection in the Solar–Terrestrial Relation

et al. 2020

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A major subset of solar-terrestrial relations, responsible, in particular, for the driver of space weather phenomena, is the interaction between the Earth's magnetosphere and the solar wind. As one of the most important modes of the solar-wind-magnetosphere interaction, magnetic reconnection regulates the energy transport and energy release in the solar-terrestrial relation. In situ measurements in the near-Earth space are crucial for understanding magnetic reconnection. Past and existing spacecraft constellation missions mainly focus on the measurement of reconnection on plasma kinetic-scales. Resolving the macro-scale and cross-scale aspects of magnetic reconnection is necessary for accurate assessment and predictions of its role in the context of space weather. Here, we propose the AME (self-Adaptive Magnetic reconnection Explorer) mission consisting of a cross-scale constellation of 12+ CubeSats and one mother satellite. Each CubeSat is equipped with instruments to measure magnetic fields and thermal plasma particles. With multiple CubeSats, the AME constellation is intended to make simultaneous measurements at multiple scales, capable of exploring cross-scale plasma processes ranging from kinetic scale to macro scale.

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“…Magnetic reconnection is arguably the most important energy conversion and transport process in collisionless plasmas. Magnetic reconnection is believed to be a key driver in astrophysical plasmas (e.g., Uzdensky, 2011), the mechanism behind solar eruptions (e.g., Antiochos et al., 1999), and it facilitates both energy entry into the magnetosphere as well as energy dissipation inside the magnetosphere (e.g., M. Hesse and Cassak, 2020). For these reasons, magnetic reconnection is also the ultimate engine behind many of the deleterious effects associated with space weather.…”

Section: Introductionmentioning

confidence: 99%

A New Look at the Electron Diffusion Region in Asymmetric Magnetic Reconnection

et al. 2021

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Magnetic reconnection is arguably the most important energy conversion and transport process in collisionless plasmas. Magnetic reconnection is believed to be a key driver in astrophysical plasmas (e.g., Uzdensky, 2011), the mechanism behind solar eruptions (e.g., Antiochos et al., 1999), and it facilitates both energy entry into the magnetosphere as well as energy dissipation inside the magnetosphere (e.g., M. Hesse and Cassak, 2020). For these reasons, magnetic reconnection is also the ultimate engine behind many of the deleterious effects associated with space weather. For both reasons of basic physical understanding as well as space weather-related applications reconnection has been a prime space physics research target. This began early on in solar research and continues Abstract A new look at the structure of the electron diffusion region in collision less magnetic reconnection is presented. The research is based on a particle-in-cell simulation of asymmetric magnetic reconnection, which includes a temperature gradient across the current layer in addition to density and magnetic field gradient. We find that none of X-point, flow stagnation point, and local current density peak coincide. Current and energy balance analyses around the flow stagnation point and current density peak show consistently that current dissipation is associated with the divergence of nongyrotropic electron pressure. Furthermore, the same pressure terms, when combined with shear-type gradients of the electron flow velocity, also serve to maintain local thermal energy against convective losses. These effects are similar to those found also in symmetric magnetic reconnection. In addition, we find here significant effects related to the convection of current, which we can relate to a generalized diamagnetic drift by the nongyrotropic pressure divergence. Therefore, only part of the pressure force serves to dissipate the current density. However, the prior conclusion that the role of the reconnection electric field is to maintain the current density, which was obtained for a symmetric system, applies here as well. Finally, we discuss related features of electron distribution function in the electron diffusion region (EDR). Specifically, we analyze both new crescent substructures as well as outer, higher energy crescents generated by accelerated magnetospheric particles. Plain Language Summary Magnetic reconnection is arguably the most important mechanism to release energy stored in magnetic fields explosively. Magnetic reconnection is believed to be the driver between as diverse a set of phenomena as solar eruptions, astrophysical radiation bursts, magnetic storms in near-Earth space, and the aurora. Quite amazingly, magnetic reconnection facilitates energy conversion over huge regions of space with size of many Earth radii by means of a tiny core region, the so-called diffusion region, with dimensions of a few to a few hundreds of kilometers. The delicate interaction between charged particles and electromagnetic fields in this central re...

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Magnetic Reconnection in the Space Sciences: Past, Present, and Future

Cited by 111 publications

References 106 publications

Coronal heating problem solution by means of axion origin photons

Coronal heating problem solution by means of axion origin photons

AME: A Cross-Scale Constellation of CubeSats to Explore Magnetic Reconnection in the Solar–Terrestrial Relation

A New Look at the Electron Diffusion Region in Asymmetric Magnetic Reconnection

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