Multi-scale deep learning for estimating horizontal velocity fields on the solar surface

Ishikawa, Ryohtaroh T.; Nakata, M.; Katsukawa, Y.; Masada, Youhei; Riethmüller, T. L.

doi:10.1051/0004-6361/202141743

Cited by 11 publications

(5 citation statements)

References 42 publications

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“…A trial use of LCT-Flowmaker with fusion plasma data will be performed in future. In addition, a deep learning based velocity field estimation technique has recently been developed [24]. An application of this approach to magnetic plasma fusion data is also underway.…”

Section: Resultsmentioning

confidence: 99%

A Comparison of Velocimetry Algorithms: Orthogonal Dynamic Programming Based Particle Image Velocimetry Versus Local Correlation Tracking

Kobayashi

Ishikawa

Nakata

et al. 2023

Plasma and Fusion Research

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In the magnetic plasma fusion community and the solar physics research community, different velocimetry algorithms have been used. Those are: orthogonal dynamic programing based particle image velocimetry (ODP-PIV) and local correlation tracking (LCT), respectively. In this paper, a systematic comparison of these velocimetry codes is performed using synthetically produced turbulence data. The spatial scale of a typical turbulence pattern is scanned to examine the sensitivity of these codes on the tracer pattern property. Use of an LCT code is recommended when the ratio of the turbulence pattern size to the spatial resolution is small. c

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Section: Resultsmentioning

confidence: 99%

A Comparison of Velocimetry Algorithms: Orthogonal Dynamic Programming Based Particle Image Velocimetry Versus Local Correlation Tracking

Kobayashi

Ishikawa

Nakata

et al. 2023

Plasma and Fusion Research

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“…This, then, presents a clear avenue for improvement, particularly when DKIST observations with higher spatial resolution (down to 0 03; Rimmele et al 2020) become available, since features in IGLs are especially vulnerable to resolution effects. Another way to improve the neural network approach is to train it to match coherence spectra, i.e., to match velocities at different frequencies in the Fourier space, as was done in Ishikawa et al (2022).…”

Section: Discussionmentioning

confidence: 99%

Quantifying Poynting Flux in the Quiet Sun Photosphere

Tilipman,

Kazachenko,

Tremblay

et al. 2023

ApJ

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Poynting flux is the flux of magnetic energy, which is responsible for chromospheric and coronal heating in the solar atmosphere. It is defined as a cross product of the electric and magnetic fields, and in ideal MHD conditions it can be expressed in terms of the magnetic field and plasma velocity. Poynting flux has been computed for active regions and plages, but estimating it in the quiet Sun (QS) remains challenging due to resolution effects and polarimetric noise. However, with the upcoming DKIST capabilities, such estimations will become more feasible than ever before. Here, we study QS Poynting flux in SUNRISE/IMaX observations and MURaM simulations. We explore two methods for inferring transverse velocities from observations—FLCT and a neural network–based method DeepVel—and show DeepVel to be the more suitable method in the context of small-scale QS flows. We investigate the effect of azimuthal ambiguity on Poynting flux estimates, and we describe a new method for azimuth disambiguation. Finally, we use two methods for obtaining the electric field. The first method relies on an idealized Ohm’s law, whereas the second is a state-of-the-art inductive electric field inversion method PDFI_SS. We compare the resulting Poynting flux values with theoretical estimates for chromospheric and coronal energy losses and find that some of the Poynting flux estimates are sufficient to match the losses. Using MURaM simulations, we show that photospheric Poynting fluxes vary significantly with optical depth, and that there is an observational bias that results in underestimated Poynting fluxes due to an unaccounted shear term contribution.

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“…We utilize a larger λ ⊥,* value than that commonly applied in past studies (∼150 km, Cranmer & Saar 2011;Shoda et al 2020;Shoda & Takasao 2021). This is attributed to the energy-containing scale in the horizontal velocity field of the photosphere resembling the granular scale (∼1000 km; Matsumoto & Shibata 2010;Ishikawa et al 2022). Given that the larger convective structures persist to higher altitudes (Kostik et al 2009), the granular scale is expected to be greater in the upper atmosphere.…”

Section: Alfvén-wave Turbulencementioning

confidence: 99%

Formulating Mass-loss Rates for Sun-like Stars: A Hybrid Model Approach

Shoda,

Cranmer,

Toriumi

2023

ApJ

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We observe an enhanced stellar wind mass-loss rate from low-mass stars exhibiting higher X-ray flux. This trend, however, does not align with the Sun, where no evident correlation between X-ray flux and mass-loss rate is present. To reconcile these observations, we propose a hybrid model for the stellar wind from solar-type stars, incorporating both Alfvén wave dynamics and flux emergence-driven interchange reconnection, an increasingly studied concept guided by the latest heliospheric observations. For establishing a mass-loss rate scaling law, we perform a series of magnetohydrodynamic simulations across varied magnetic activities. Through a parameter survey concerning the surface (unsigned) magnetic flux (Φsurf) and the open-to-surface magnetic flux ratio (ξ open = Φopen/Φsurf), we derive a scaling law of the mass-loss rate given by M ̇ w / M ̇ w , ⊙ = Φ surf / Φ ⊙ surf 0.52 ξ open / ξ ⊙ open 0.86 , where M ̇ w , ⊙ = 2.0 × 10 − 14 M ⊙ yr − 1 , Φ ⊙ surf = 3.0 × 10 23 Mx , and ξ ⊙ open = 0.2 . By comparing cases with and without flux emergence, we find that the increase in the mass-loss rate with the surface magnetic flux can be attributed to the influence of flux emergence. Our scaling law demonstrates an agreement with solar wind observations spanning 40 yr, exhibiting superior performance when compared to X-ray-based estimations. Our findings suggest that flux emergence may play a significant role in the stellar winds of low-mass stars, particularly those originating from magnetically active stars.

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Multi-scale deep learning for estimating horizontal velocity fields on the solar surface

Cited by 11 publications

References 42 publications

A Comparison of Velocimetry Algorithms: Orthogonal Dynamic Programming Based Particle Image Velocimetry Versus Local Correlation Tracking

A Comparison of Velocimetry Algorithms: Orthogonal Dynamic Programming Based Particle Image Velocimetry Versus Local Correlation Tracking

Quantifying Poynting Flux in the Quiet Sun Photosphere

Formulating Mass-loss Rates for Sun-like Stars: A Hybrid Model Approach

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