Comparison of test particle acceleration in torsional spine and fan reconnection regimes

Hosseinpour, M.; Mehdizade, M; Mohammadi, M. A.

doi:10.1063/1.4898311

Cited by 9 publications

(7 citation statements)

References 27 publications

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“…After this peak kinetic energy gain, the total energy of each particle is rapidly lost due to collisional effects ((2.16), black dotted lines) as the particles propagate away from the regions of strong electric potential. The shape of the initially rapid kinetic energy gains of the acceleration phases (red lines, figure 7c, f and figure 7d,g; ≈1300-1600 time steps) follow the behaviour found in similar particle energization simulations of both torsional fan and torsional spine reconnection (Dalla & Browning 2005Stanier et al 2012;Hosseinpour 2014aHosseinpour ,b, 2015Hosseinpour et al 2014;Gascoyne 2015). However, those simulations were rooted in the collisionless nature of solar coronal conditions, whereas here a more resistive plasma nature contributes strongly to total energy loss.…”

Section: Single Particle Behavioursupporting

confidence: 71%

“…where distances are scaled to a characteristic length described in § § 2.2 and 3.2, j, l and c govern the degree and spatial extent of the twist, and β and γ are positive integers. Throughout this paper, we set j = 5, γ = 3, l = 1 and β = c = 0, corresponding to a generic radially linear perturbation, and consistent with the torsional fan reconnection simulations of Hosseinpour (2015), Hosseinpour (2014a) and Hosseinpour et al (2014). Using these values, (2.1) reduces to…”

Section: Field Structurementioning

confidence: 99%

“…The initial study of Chesny et al (2017) described a feasible apparatus that achieved both of the previous conditions, but stopped short of demonstrating particle response to reconnection. Numerous authors (Dalla & Browning 2005Stanier, Browning & Dalla 2012;Hosseinpour, Mehdizade & Mohammadi 2014;Gascoyne 2015;Threlfall et al 2015;Pallister, Pontin & Wyper 2019) have employed a test particle approach to demonstrate relativistic particle acceleration in torsional reconnection under collisionless solar plasma conditions. These studies were able to broadly confirm satellite observations of the acceleration of protons to ∼ 10 MeV levels and the formation of collimated, bidirectional jets.…”

Section: Introductionmentioning

confidence: 99%

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Test particle acceleration in resistive torsional fan magnetic reconnection using laboratory plasma parameters

Chesny¹,

Orange

Hatfield

2021

J. Plasma Phys.

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Particle acceleration via magnetic reconnection is a fundamental process in astrophysical plasmas. Experimental architectures are able to confirm a wide variety of particle dynamics following the two-dimensional Sweet–Parker model, but are limited in their reproduction of the fan-spine magnetic field topology about three-dimensional (3-D) null points. Specifically, there is not yet an experiment featuring driven 3-D torsional magnetic reconnection. To move in this direction, this paper expands on recent work toward the design of an experimental infrastructure for inducing 3-D torsional fan reconnection by predicting feasible particle acceleration profiles. Solutions to the steady-state, kinematic, resistive magnetohydrodynamic equations are used to numerically calculate particle trajectories from a localized resistivity profile using well-understood laboratory plasma parameters. We confine a thin, 10 eV helium sheath following the snowplough model into the region of this localized resistivity and find that it is accelerated to energies of ${\approx }2$ keV. This sheath is rapidly accelerated and focused along the spine axis propagating a few centimetres from the reconnection region. These dynamics suggest a novel architecture that may hold promise for future experiments studying solar coronal particle acceleration and for technology applications such as spacecraft propulsion.

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Section: Single Particle Behavioursupporting

confidence: 71%

Section: Field Structurementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Test particle acceleration in resistive torsional fan magnetic reconnection using laboratory plasma parameters

Chesny¹,

Orange

Hatfield

2021

J. Plasma Phys.

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“…In such a configuration, the vicinity of the original null becomes highly turbulent, and one would expect efficient particle scattering along both the large-scale spine and fan directions. Second, if there is some large-scale rotational external motion, this can drive torsional spine reconnection, associated with a component of current parallel to the spine which can accelerate particles along the spine (Hosseinpour, Mehdizade, and Mohammadi, 2014). Finally, one could expect strong mirroring of particles close to the fan footpoints to lead to a distribution of particles also around the spine footpoints (note that the PIC simulations of Baumann, Haugbølle, and Nordlund (2013) did not cover the domain all the way to the photosphere).…”

Section: Predicting Flare Ribbon Locationsmentioning

confidence: 99%

Why Are Flare Ribbons Associated with the Spines of Magnetic Null Points Generically Elongated?

Pontin

Galsgaard²,

Démoulin

2016

Sol Phys

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Coronal magnetic null points exist in abundance, as demonstrated by extrapolations of the coronal field, and have been inferred to be important for a broad range of energetic events. These null points and their associated separatrix and spine field lines represent discontinuities of the field line mapping, making them preferential locations for reconnection. This field line mapping also exhibits strong gradients adjacent to the separatrix (fan) and spine field lines, which can be analysed using the "squashing factor", Q. In this article we analyse in detail the distribution of Q in the presence of magnetic nulls. While Q is formally infinite on both the spine and fan of the null, the decay of Q away from these structures is shown in general to depend strongly on the null-point structure. For the generic case of a non-radially-symmetric null, Q decays most slowly away from the spine or fan in the direction in which |B| increases most slowly. In particular, this demonstrates that the extended elliptical high-Q halo around the spine footpoints observed by Masson et al. (Astrophys. J. 700, 559, 2009) is a generic feature. This extension of the Q halos around the spine or fan footpoints is important for diagnosing the regions of the photosphere that are magnetically connected to any current layer that forms at the null. In light of this, we discuss how our results can be used to interpret the geometry of observed flare ribbons in circular ribbon flares, in which typically a coronal null is implicated. We conclude that both the physics in the vicinity of the null and how this is related to the extension of Q away from the spine or fan can be used in tandem to understand observational signatures of reconnection at coronal null points.

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“…While their analysis was based on X-point plasma outflows of the order of the local v A that are possible in existing spheromak and tokamak-style laboratory configurations (Cazzola et al 2016), any practical, mass-constrained spacecraft application would require explicit control of a centimetre-scale highly compact plasma sheet concentrated along open magnetic field lines, such as that explored here, that can propagate far from the reconnection region. The TSR mode has been suggested to be a highly efficient mechanism for accelerating injected particles to spine-aligned relativistic velocities on fast ∼ms time scales (Hosseinpour 2014;Hosseinpour, Mehdizade & Mohammadi 2014). Issues of plasma confinement and losses present in other plasma propulsion systems could also be significantly decreased, as TSR mode charged particle acceleration is only efficient close to the rotational perturbation region (Hosseinpour 2014), e.g.…”

Section: Discussionmentioning

confidence: 99%

Toward laboratory torsional spine magnetic reconnection

Chesny¹,

Orange²,

Oluseyi

et al. 2017

J. Plasma Phys.

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Magnetic reconnection is a fundamental energy conversion mechanism in nature. Major attempts to study this process in controlled settings on Earth have largely been limited to reproducing approximately two-dimensional (2-D) reconnection dynamics. Other experiments describing reconnection near three-dimensional null points are non-driven, and do not induce any of the 3-D modes of spine fan, torsional fan or torsional spine reconnection. In order to study these important 3-D modes observed in astrophysical plasmas (e.g. the solar atmosphere), laboratory set-ups must be designed to induce driven reconnection about an isolated magnetic null point. As such, we consider the limited range of fundamental resistive magnetohydrodynamic (MHD) and kinetic parameters of dynamic laboratory plasmas that are necessary to induce the torsional spine reconnection (TSR) mode characterized by a driven rotational slippage of field lines – a feature that has yet to be achieved in operational laboratory magnetic reconnection experiments. Leveraging existing reconnection models, we show that within a ${\lesssim}1~\text{m}^{3}$ apparatus, TSR can be achieved in dense plasma regimes (${\sim}10^{24}~\text{m}^{-3}$) in magnetic fields of ${\sim}10^{-1}~\text{T}$. We find that MHD and kinetic parameters predict reconnection in thin ${\lesssim}20~\unicode[STIX]{x03BC}\text{m}$ current sheets on time scales of ${\lesssim}10~\text{ns}$. While these plasma regimes may not explicitly replicate the plasma parameters of observed astrophysical phenomena, studying the dynamics of the TSR mode within achievable set-ups signifies an important step in understanding the fundamentals of driven 3-D magnetic reconnection and the self-organization of current sheets. Explicit control of this reconnection mode may have implications for understanding particle acceleration in astrophysical environments, and may even have practical applications to fields such as spacecraft propulsion.

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Comparison of test particle acceleration in torsional spine and fan reconnection regimes

Cited by 9 publications

References 27 publications

Test particle acceleration in resistive torsional fan magnetic reconnection using laboratory plasma parameters

Test particle acceleration in resistive torsional fan magnetic reconnection using laboratory plasma parameters

Why Are Flare Ribbons Associated with the Spines of Magnetic Null Points Generically Elongated?

Toward laboratory torsional spine magnetic reconnection

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