2005
DOI: 10.1051/0004-6361:20042043
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Solar atmospheric model with spicules applied to radio observation

Abstract: Abstract. An atmospheric model was constructed in order to reproduce quantitatively the observations at 17 GHz from Nobeyama Radio Heliograph, namely the brightness temperature at disk center (from 1.4 to 400 GHz), center-to-limb brightening distribution, and radius derived from 17 GHz solar maps. The two dimensional solar atmospheric model, that takes into account the curvature of the Sun, includes spicules, which physical characteristics (such as size, temperature, density, position, and inclination angle) w… Show more

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Cited by 53 publications
(81 citation statements)
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“…The magnetic field at zero height is the photospheric longitudinal magnetic field measured by HMI. This field does not fill the radio-polarized region at a height of 5220 km, which corresponds to the bottom of the corona in the atmospheric model of Selhorst et al (2005). On the other hand, at a height of 20,880 km, the longitudinal magnetic field appears to be distributed throughout the contour of the polarization degree.…”
Section: Comparison With the Potential Field Modelmentioning
confidence: 86%
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“…The magnetic field at zero height is the photospheric longitudinal magnetic field measured by HMI. This field does not fill the radio-polarized region at a height of 5220 km, which corresponds to the bottom of the corona in the atmospheric model of Selhorst et al (2005). On the other hand, at a height of 20,880 km, the longitudinal magnetic field appears to be distributed throughout the contour of the polarization degree.…”
Section: Comparison With the Potential Field Modelmentioning
confidence: 86%
“…Since the derived coronal longitudinal magnetic fields estimated from EIS observations were still the upper limit, we should estimate the actual coronal magnetic field by using some assumptions. The millimeter-range brightness temperatures in the quiet region have been observed (e.g., Kuseki & Swanson 1976) and modeled (Selhorst et al 2005). According to Selhorst et al (2005), the brightness temperature of the quiet region at 34 GHz is about 9000 K. The height of the optically thick layer at 17 GHz should be higher than that of at 34 GHz because the temperature in the chromosphere is a monotonically increasing function of height.…”
Section: The Effect Of the Low-temperature Plasmamentioning
confidence: 99%
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“…The atmospheric model previously developed (Selhorst et al 2005) consists of temperature and density (electron and proton) distributions as a function of height, from the photosphere up to 40 000 km in the corona. The SSC model was developed as a bi-dimensional space reproducing one quadrant of the Sun.…”
Section: The Ssc Modelmentioning
confidence: 99%
“…In a previous work, Selhorst et al (2005) developed an atmospheric model (hereafter referred to as the SSC model) in order to reproduce simultaneously three independent radio observations: the brightness temperature at disk center for frequencies ranging from 1.4 to 400 GHz, the observations of the radius and the limb brightening at 17 GHz. Moreover, the SSC is a 2-D model that takes into account the solar spherical curvature in order to study the solar radius and the limb brightening at 17 GHz.…”
Section: Introductionmentioning
confidence: 99%