What Causes the Inter-Solar-Cycle Variation of Total Solar Irradiance?

Xiang, N. B.; Kong, D. F.

doi:10.1088/0004-6256/150/6/171

Cited by 22 publications

(8 citation statements)

References 54 publications

(69 reference statements)

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“…Moreover, the long-term part of the Mg II index shows the small magnetic features contribution to the intensification of TSI [9,12]. Consequently, our finding validates that the solar cycle variation of TSI is dominated by the small magnetic features on the solar full disk, which somewhat coincides with early studies [12,14,15]. It is known that the small-scale magnetic elements, which populate (and form) the faculae in active regions and quiet Sun network/internetwork [57][58][59], are bright and raise the energy transportation from the solar interior toward the solar surface, since the darkness is overcome by the lateral heating in the small-scale magnetic concentrations [4,53,[60][61][62].…”

Section: Conclusion and Discussionsupporting

confidence: 89%

“…The TSI was first measured by radiometer on board satellites in October 1978, and space-based measurements have continued for more than 40 years. The satellite measurements near Earth show that the TSI varies at all of the timescales it is measured; that is, it varies from solar minimum to maximum, and from one cycle to the next [6][7][8][9][10][11][12][13][14][15][16]. It is generally accepted that the variations of TSI on timescales of minutes to hours are mainly related to granulation, mesogranulation, and supergranulation [17], and the variations in TSI on timescales of a few days to weeks are dominated by the evolution of magnetic features on the solar surface [12,17,18].…”

Section: Introductionmentioning

confidence: 99%

“…Fröhlich [9] advised that the solar cycle variation of TSI is probably due to a change of the global temperature of the Sun modulated by the strength of activity but not modulated by the surface magnetism as the solar cycle modulation. Xiang and Kong [15] investigated the relation between TSI and magnetic fields and found that the weak magnetic activity seen on the solar full disk dominates the solar cycle variation of TSI. This result is the same as the finding in Li et al [22], in which the conclusion is based on the phase relations between TSI and Mg II core-to-wing ratio.…”

Section: Introductionmentioning

confidence: 99%

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Revisiting the Question: The Cause of the Solar Cycle Variation of Total Solar Irradiance

Xiang

2019

Advances in Astronomy

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The Mg II index and sunspot area are usually used to represent the intensification contribution by solar bright structures to total solar irradiance (TSI) and sunspot darkening, respectively. In order to understand the cause of the solar cycle variation of TSI, we use extension of wavelet transform, wavelet coherence (WTC), and partial wavelet coherence (PWC), to revisit this issue. The WTC of TSI with sunspot area shows that the two time series are very coherent on timescales of one solar cycle, but the PWC of TSI with sunspot area, which can find the results of WTC after eliminating the effect of the Mg II index, indicates that the solar cycle variation of TSI is not related to sunspots on the solar surface. The coherence of two time series at these timescales should be due to a particular phase relation between sunspots and TSI. The WTC and PWC of TSI with Mg II index show that the solar cycle variation of TSI is highly related to Mg II index, which reflects the relation of TSI with the long-term part of Mg II index that shows the intensification contribution by the small magnetic features to TSI. Consequently, the solar cycle variation of TSI is dominated by the small magnetic features on the solar full disk. Additionally, we also show the combined effects of the sunspot darkening and the intensification contribution represented by Mg II index to TSI on timescales of a few days to several months and indicate that the faculae increase TSI and contribute to its variation at these timescales.

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Section: Conclusion and Discussionsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Revisiting the Question: The Cause of the Solar Cycle Variation of Total Solar Irradiance

Xiang

2019

Advances in Astronomy

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“…One of its extension, the cross-wavelet transform (CWT), can be applied to determine the relative phase difference between the two time series (Grinsted et al 2004). This technique has been successful used in a broad range of research aspects of solar physics fields, such as Xiang & Kong (2015), Roberts et al (2017), Xu et al (2017), Gil & Mursula (2018), Keys et al (2018), and so on.…”

Section: Phase Relationship Between Coronal Rotation and Solar Activitymentioning

confidence: 99%

Systematic regularity of solar coronal rotation during the time interval 1939–2019

Deng

Zhang

Deng

et al. 2019

Monthly Notices of the Royal Astronomical Society

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Temporal variation of the solar coronal rotation appears to be very complex and its relevances to the eleven-year solar activity cycle are still unclear. Using the modified coronal index for the time interval from 1939 January 1 to 2019 May 31, the systematic regularities of the solar coronal rotation are investigated. Our main findings are as follows: (1) from a global point of view, the synodic coronal rotation period with a value of 27.5 days is the only significant period at the periodic scales shorter than 64 days; (2) the coronal rotation period exhibit an obviously decreasing trend during the considered time interval, implying the solar corona accelerates its global rotation rate in the long run; (3) there exist significant periods of 3.25, 6.13, 9.53, and 11.13 years in the period length of the coronal rotation, providing an evidence that the coronal rotation should be connected with the quasi-biennial oscillation, the eleven-year solar cycle, and the 22-year Hale cycle (or the magnetic activity reversal); and (4) the phase relationship between the coronal rotation period and the solar magnetic activity is not only time-dependent but also frequency-dependent. For a small range around the 11-year cycle band, there is a systematic trend in the phase, and the small mismatch in this band brings out the phase to drift. The possible mechanism for the above analysis results is discussed.

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“…Sunspots are the dark parts those are cooler (around 4500 K) than the surrounding area in the photosphere of the Sun, and they are as large as 5000 miles in diameter [9]. Solar magnetic fields are formed below the surface atmosphere and extend put into the corona which owns high temperature.…”

Section: Astronomical Data Archivesmentioning

confidence: 99%

Multi-scale Oscillation Modes and Secular Trend Analysis of Astronomical Historic Archives

Zuo¹,

Cai²,

Liu³

et al. 2019

IJAPM

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Studies on astronomical historic archives are very important for understanding and promoting the progress of astronomy and astrophysics. For long-term solar data sets, they are the oldest topics in statistical astrophysics during the last four hundred years. To reveal the complex physical behavior of solar magnetic structures, a relatively novel time series analysis technique is applied here to investigate the multi-scale oscillation modes and the secular trend of yearly solar sunspot areas during the time interval from 1611 to 2005. Based on the empirical mode decomposition technique, the following results are found: 1) the time series of 395-year solar sunspot areas is decomposed into four intrinsic mode functions with different quasi-periodic oscillations, which could be understood four dynamic processes that have different periodic-scales; 2) for the secular trend of solar magnetic activity, the level of the Sun has a rapid decrease from 1611 to 1670, and then the activity level increases during the period of 1670-2005. The analysis results indicate that the utility of the empirical mode decomposition technique for the study of solar historic archives and could provide some very important information on the understanding of solar magnetic activity variations.

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What Causes the Inter-Solar-Cycle Variation of Total Solar Irradiance?

Cited by 22 publications

References 54 publications

Revisiting the Question: The Cause of the Solar Cycle Variation of Total Solar Irradiance

Revisiting the Question: The Cause of the Solar Cycle Variation of Total Solar Irradiance

Systematic regularity of solar coronal rotation during the time interval 1939–2019

Multi-scale Oscillation Modes and Secular Trend Analysis of Astronomical Historic Archives

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