用绝对校准碘电池光谱法测量太阳差转率

IF 2.7 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Yoichi Takeda
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引用次数: 0

摘要

众所周知,碘电池技术能有效地精确确定多普勒速度偏移,作者曾将其用于测量基于全圆盘光谱观测的太阳差转(Takeda 和 Ueno,2011 年)。然而,其中采用的数据缩减程序(与恒星情况简单类比)并不一定充分,因为没有适当考虑到磁盘分辨太阳的一个特定特征(即线强度的中心-边缘变化)。因此,我们基于相同的数据重新研究了这个问题,但将其应用于理论光谱拟合,这样就能以一致的方式得出绝对日心径向速度(\(v_{\mathrm{obs}}\)),正如太阳引力红移研究中所显示的那样(Takeda 和 Ueno,2012 年)。同样,在每个圆盘点将\(v_{mathrm{obs}}\)转换成\(\omega \)(角速度)会产生相当大的误差,尤其是在中央子午线附近,而这次则是通过对包含许多点的\(v_{mathrm{obs}}\)值的数据集进行最小二乘法分析得出\(\omega \)。这一新的分析得出了 \(\omega \) (deg day-1) = \(13.92 (\pm 0.03) -1.69(\pm 0.34)\sin ^{2}\psi -2.37(\pm 0.62) \sin ^{4}\psi \) (\(\psi \):日光纬度)以及 675 m s-1 的引力红移,这些数据与之前发表的数据相比都很不错。此外,我们还研究了观测点在星盘上的分布对结果的影响,结果表明旋转参数在不同情况下可能会出现明显的误差。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Measurement of Solar Differential Rotation by Absolutely Calibrated Iodine-Cell Spectroscopy

Measurement of Solar Differential Rotation by Absolutely Calibrated Iodine-Cell Spectroscopy

Measurement of Solar Differential Rotation by Absolutely Calibrated Iodine-Cell Spectroscopy

The iodine-cell technique, which is known to be efficient in precisely establishing Doppler velocity shifts, was once applied by the author to measuring the solar differential rotation based on full-disk spectroscopic observations (Takeda and Ueno 2011). However, the data reduction procedure (in simple analogy with the stellar case) adopted therein was not necessarily adequate, because a specific characteristic involved with the disk-resolved Sun (i.e., center–limb variation of line strengths) was not properly taken into consideration. Therefore this problem is revisited based on the same data but with an application to theoretical spectrum fitting, which can yield absolute heliocentric radial velocities (\(v_{\mathrm{obs}}\)) in a consistent manner as shown in the study of solar gravitational redshift (Takeda and Ueno 2012). Likewise, instead of converting \(v_{\mathrm{obs}}\) into \(\omega \) (angular velocity) at each disk point, which suffers considerable errors especially near the central meridian, \(\omega \) is derived this time by applying the least squares analysis to a dataset comprising \(v_{\mathrm{obs}}\) values at many points. This new analysis resulted in \(\omega \) (deg day−1) = \(13.92 (\pm 0.03) -1.69(\pm 0.34)\sin ^{2}\psi -2.37(\pm 0.62) \sin ^{4}\psi \) (\(\psi \): the heliographic latitude) along with the gravitational redshift of 675 m s−1, which are favorably compared with previous publications. In addition, how the distribution of observing points on the disk affects the result is also examined, which reveals that rotation parameters may suffer appreciable errors depending on cases.

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来源期刊
Solar Physics
Solar Physics 地学天文-天文与天体物理
CiteScore
5.10
自引率
17.90%
发文量
146
审稿时长
1 months
期刊介绍: Solar Physics was founded in 1967 and is the principal journal for the publication of the results of fundamental research on the Sun. The journal treats all aspects of solar physics, ranging from the internal structure of the Sun and its evolution to the outer corona and solar wind in interplanetary space. Papers on solar-terrestrial physics and on stellar research are also published when their results have a direct bearing on our understanding of the Sun.
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