Magnetic Upflow Events in the Quiet-Sun Photosphere. I. Observations

Jafarzadeh, S.; Voort, L. H. M. Rouppe van der; Rodríguez, J. de la Cruz

doi:10.1088/0004-637x/810/1/54

Cited by 8 publications

(4 citation statements)

References 49 publications

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“…To detect LPFs in the differently treated LP maps, we employ an algorithm developed by Jafarzadeh, Rouppe van der Voort, and de la Cruz Rodríguez ( 2015 ). In detection procedure, the LP signal in a given LP map is cut at a certain signal threshold, which is defined as a factor of noise level (see Figure 2 ).…”

Section: Analysis and Resultsmentioning

confidence: 99%

Linear Polarization Features in the Quiet-Sun Photosphere: Structure and Dynamics

et al. 2018

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We present detailed characteristics of linear polarization features (LPFs) in the quiet-Sun photosphere from high-resolution observations obtained with Sunrise/IMaX. We explore differently treated data with various noise levels in linear polarization signals, from which structure and dynamics of the LPFs are studied. Physical properties of the detected LPFs are also obtained from the results of Stokes inversions. The number of LPFs and their sizes and polarization signals are found to be strongly dependent on the noise level and on the spatial resolution. While the linear polarization with a signal-to-noise ratio covers about 26% of the entire area in the least noisy data in our study (with a noise level of in the unit of Stokes continuum), the detected (spatially resolved) LPFs cover about 10% of the area at any given time, with an occurrence rate on the order of arcsec−2. The LPFs were found to be short lived (in the range of 30 – 300 s), relatively small structures (radii of – 1.5 arcsec), highly inclined, posing hG fields, and they move with an average horizontal speed of 1.2 km s−1. The LPFs were observed (almost) equally on both upflow and downflow regions, with an intensity contrast always larger than that of the average quiet Sun.

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Section: Analysis and Resultsmentioning

confidence: 99%

Linear Polarization Features in the Quiet-Sun Photosphere: Structure and Dynamics

et al. 2018

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“…These high speed velocities are usually translated into characteristic spectral features. From highly dopplershifted circular polarization signals with complex profile shapes as single-lobed (Borrero et al 2010;Quintero Noda et al 2014a;Jafarzadeh et al 2015) or multi-lobed profiles (Shimizu et al 2008a;Quintero Noda et al 2014b) to secondary satellite lobes in the intensity profiles (Bellot Rubio 2009). The reason behind this high speed plasma is still under debate and it seems that there is not a single answer.…”

Section: Introductionmentioning

confidence: 99%

Analysis of horizontal flows in the solar granulation

Noda

Shimizu

Suematsu

2016

Mon. Not. R. Astron. Soc.

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Solar limb observations sometimes reveal the presence of a satellite lobe in the blue wing of the Stokes I profile from pixels belonging to granules. The presence of this satellite lobe has been associated in the past to strong line of sight gradients and, as the line of sight component is almost parallel to the solar surface, to horizontal granular flows. We aim to increase the knowledge about these horizontal flows studying a spectropolarimetric observation of the north solar pole. We will make use of two state of the art techniques, the spatial deconvolution procedure that increases the quality of the data removing the stray light contamination, and spectropolarimetric inversions that will provide the vertical stratification of the atmospheric physical parameters where the observed spectral lines form. We inverted the Stokes profiles using a two component configuration, obtaining that one component is strongly blueshifted and displays a temperature enhancement at upper photospheric layers while the second component has low redshifted velocities and it is cool at upper layers. In addition, we examined a large number of cases located at different heliocentric angles, finding smaller velocities as we move from the centre to the edge of the granule. Moreover, the height location of the enhancement on the temperature stratification of the blueshifted component also evolves with the spatial location on the granule being positioned on lower heights as we move to the periphery of the granular structure.

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“…To that end, we took the simulations of Vigeesh et al [49] and we used the NICOLE [23] code to synthesize the emergent Stokes profiles for both the moderate field and strong field simulations for the Fe ɪ 6301 Å and 6302 Å line pair. We chose these lines as they are commonly used lines in spectropolarimetric observations of small-scale magnetic fields [30,32,37,62,63]. Also, it has been noted that inverting multiple lines in tandem, may improve the resulting outputs [4,64], therefore, we wished to match as close as possible expected observation regimes for these facilities.…”

Section: Methodsmentioning

confidence: 99%

On the effect of oscillatory phenomena on Stokes inversion results

Keys

Steiner

Vigeesh

2020

Phil. Trans. R. Soc. A.

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Stokes inversion codes are crucial in returning properties of the solar atmosphere, such as temperature and magnetic field strength. However, the success of such algorithms to return reliable values can be hindered by the presence of oscillatory phenomena within magnetic wave guides. Returning accurate parameters is crucial to both magnetohydrodynamics (MHD) studies and solar physics in general. Here, we employ a simulation featuring propagating MHD waves within a flux tube with a known driver and atmospheric parameters. We invert the Stokes profiles for the 6301 Å and 6302 Å line pair emergent from the simulations using the well-known Stokes Inversions from Response functions code to see if the atmospheric parameters can be returned for typical spatial resolutions at ground-based observatories. The inversions return synthetic spectra comparable to the original input spectra, even with asymmetries introduced in the spectra from wave propagation in the atmosphere. The output models from the inversions match closely to the simulations in temperature, line-of-sight magnetic field and line-of-sight velocity within typical formation heights of the inverted lines. Deviations from the simulations are seen away from these height regions. The inversions results are less accurate during passage of the waves within the line formation region. The original wave period could be recovered from the atmosphere output by the inversions, with empirical mode decomposition performing better than the wavelet approach in this task. This article is part of the Theo Murphy meeting issue ‘High-resolution wave dynamics in the lower solar atmosphere’.

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Magnetic Upflow Events in the Quiet-Sun Photosphere. I. Observations

Cited by 8 publications

References 49 publications

Linear Polarization Features in the Quiet-Sun Photosphere: Structure and Dynamics

Linear Polarization Features in the Quiet-Sun Photosphere: Structure and Dynamics

Analysis of horizontal flows in the solar granulation

On the effect of oscillatory phenomena on Stokes inversion results

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