Mass-loss Rates from Coronal Mass Ejections: A Predictive Theoretical Model for Solar-type Stars

Cranmer, Steven R.

doi:10.3847/1538-4357/aa6f0e

Cited by 57 publications

(51 citation statements)

References 124 publications

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“…The presence of such fields is now definitively established for active M dwarfs (Shulyak et al 2017;Kochukhov & Shulyak 2019) and T Tauri stars (Sokal et al 2020). This suggests that local field strength is not limited by the confinement of magnetic flux tubes by the photospheric gas pressure as was repeatedly assumed in the past (Saar & Linsky 1986b;Cranmer 2017;See et al 2019).…”

Section: Correlation With Stellar Parametersmentioning

confidence: 75%

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Hidden magnetic fields of young suns

Kochukhov

Hackman

Lehtinen

et al. 2020

A&A

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Global magnetic fields of active solar-like stars are nowadays routinely detected with spectropolarimetric measurements and are mapped with Zeeman-Doppler imaging (ZDI). However, due to the cancellation of opposite field polarities, polarimetry captures only a tiny fraction of the magnetic flux and cannot assess the overall stellar surface magnetic field if it is dominated by a smallscale component. Analysis of Zeeman broadening in high-resolution intensity spectra can reveal these hidden complex magnetic fields. Historically, there were very few attempts to obtain such measurements for G dwarf stars due to the difficulty of disentangling Zeeman effect from other broadening mechanisms affecting spectral lines. Here we developed a new magnetic field diagnostic method based on relative Zeeman intensification of optical atomic lines with different magnetic sensitivity. Using this technique we obtained 78 field strength measurements for 15 Sun-like stars, including some of the best-studied young solar twins. We find that the average magnetic field strength B f drops from 1.3-2.0 kG in stars younger than about 120 Myr to 0.2-0.8 kG in older stars. The mean field strength shows a clear correlation with the Rossby number and with the coronal and chromospheric emission indicators. Our results suggest that magnetic regions have roughly the same local field strength B ≈ 3.2 kG in all stars, with the filling factor f of these regions systematically increasing with stellar activity. Comparing our results with the spectropolarimetric analyses of global magnetic fields in the same stars, we find that ZDI recovers about 1% of the total magnetic field energy in the most active stars. This figure drops to just 0.01% for the least active targets.

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Section: Correlation With Stellar Parametersmentioning

confidence: 75%

“…Information on the magnetic filling factors determined within this framework (provided that f can be reliably separated from B) is important for understanding a range of processes taking place in active cool stars (e.g. Montesinos & Jordan 1993;Cranmer & Saar 2011;Cranmer 2017;See et al 2019).…”

Section: Magnetic Spectrum Synthesismentioning

confidence: 99%

Hidden magnetic fields of young suns

Kochukhov

Hackman

Lehtinen

et al. 2020

A&A

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“…Being suddenly exposed to the stellar radiation pressure (and stellar wind) for the first time, the overdense small Qrp , wherė M is the mass-loss rate, vsw is the wind velocity, c is the speed of light, L is the stellar luminosity, and Qsw and Qrp are the efficiency factors for stellar wind and radiation pressure (assumed to be 1). Adopting a mass-loss rate of 2×10 −10 M yr −1 for a young solar-type star during a CME event (Cranmer 2017) and a wind velocity of 2000 km s −1 , this ratio is ∼20 during the enhanced stellar wind phase. dust grains (called seeds by Chiang & Fung (2017)) would collide with other particles within the cloud to generate grains of similar sizes (β-meteoroids) in an exponentially amplifying avalanche (Chiang & Fung 2017; see further discussion in Section 6.3).…”

Section: Radiation Pressure and Stellar Windmentioning

confidence: 99%

Extreme Debris Disk Variability: Exploring the Diverse Outcomes of Large Asteroid Impacts During the Era of Terrestrial Planet Formation

Jackson

Gáspár

et al. 2019

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The most dramatic phases of terrestrial planet formation are thought to be oligarchic and chaotic growth, on timescales of up to 100-200 Myr, when violent impacts occur between large planetesimals of sizes up to protoplanets. Such events are marked by the production of large amounts of debris, as has been observed in some exceptionally bright and young debris disks (termed extreme debris disks). Here we report five years of Spitzer measurements of such systems around two young solar-type stars: ID8 and P1121. The short-term (weekly to monthly) and long-term (yearly) disk variability is consistent with the aftermaths of large impacts involving large asteroid-sized bodies. We demonstrate that an impact-produced clump of optically thick dust, under the influence of the dynamical and viewing geometry effects, can produce short-term modulation in the disk light curves. The long-term disk flux variation is related to the collisional evolution within the impact-produced fragments once released into a circumstellar orbit. The time-variable behavior observed in the P1121 system is consistent with a hypervelocity impact prior to 2012 that produced vapor condensates as the dominant impact product. Two distinct short-term modulations in the ID8 system suggest two violent impacts at different times and locations. Its long-term variation is consistent with the collisional evolution of two different populations of impact-produced debris dominated by either vapor condensates or escaping boulders. The bright, variable emission from the dust produced in large impacts from extreme debris disks provides a unique opportunity to study violent events during the era of terrestrial planet formation. Subject headings: circumstellar matter -infrared: planetary systems -planets and satellites: dynamical evolution and stability -stars: individual (

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“…Our study has excluded only the full halo CMEs for which the mass is underestimated and often some of their mass could be hidden behind the occulter of the coronagraphs. The study of Cranmer (2017), by excluding the CMEs labeled as "poor" events and the ones listed without masses in the CDAW catalog, have also found that the CMEs contribute only about 3% of the background solar wind mass flux during the maximum of the cycle 23. However, in a few studies, the contribution of CMEs to solar wind mass flux in the ecliptic is found to be around 15% during the maximum of the cycle and around 3% at the minimum of the cycles (Hildner 1977;Jackson & Howard 1993;Webb & Howard 1994).…”

Section: Solar Wind Mass Loss Rate and Proxies Of Solar Cyclementioning

confidence: 99%

Mass loss via solar wind and coronal mass ejections during solar cycles 23 and 24

Mishra

Srivastava

Wang

et al. 2019

Monthly Notices of the Royal Astronomical Society

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Similar to the Sun, other stars shed mass and magnetic flux via ubiquitous quasi-steady wind and episodic stellar coronal mass ejections (CMEs). We investigate the mass loss rate via solar wind and CMEs as a function of solar magnetic variability represented in terms of sunspot number and solar X-ray background luminosity. We estimate the contribution of CMEs to the total solar wind mass flux in the ecliptic and beyond, and its variation over different phases of the solar activity cycles. The study exploits the number of sunspots observed, coronagraphic observations of CMEs near the Sun by SOHO/LASCO, in situ observations of the solar wind at 1 AU by WIND, and GOES X-ray flux during solar cycle 23 and 24. We note that the X-ray background luminosity, occurrence rate of CMEs and ICMEs, solar wind mass flux, and associated mass loss rates from the Sun do not decrease as strongly as the sunspot number from the maximum of solar cycle 23 to the next maximum. Our study confirms a true physical increase in CME activity relative to the sunspot number in cycle 24. We show that the CME occurrence rate and associated mass loss rate can be better predicted by X-ray background luminosity than the sunspot number. The solar wind mass loss rate which is an order of magnitude more than the CME mass loss rate shows no obvious dependency on cyclic variation in sunspot number and solar X-ray background luminosity. These results have implications to the study of solar-type stars.

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Mass-loss Rates from Coronal Mass Ejections: A Predictive Theoretical Model for Solar-type Stars

Cited by 57 publications

References 124 publications

Hidden magnetic fields of young suns

Hidden magnetic fields of young suns

Extreme Debris Disk Variability: Exploring the Diverse Outcomes of Large Asteroid Impacts During the Era of Terrestrial Planet Formation

Mass loss via solar wind and coronal mass ejections during solar cycles 23 and 24

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