Two Stars' Close Encounter May Explain a Flare That Lasted 85 Years

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Mercury
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Two Stars' Close Encounter May Explain a Flare That Lasted 85 Years

Post by Mercury » Tue Jan 04, 2022 6:29 pm

by Ken Croswell

A newborn star whizzing past another stellar youngster triggered a cosmic flare-up that began nearly a century ago and is still going strong today, researchers say.

The star is named FU Orionis.

Link: Science News

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neufer
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FU Orionis

Post by neufer » Wed Jan 05, 2022 3:31 am

https://en.wikipedia.org/wiki/FU_Orionis_star wrote:
Click to play embedded YouTube video.
<<In stellar evolution, an FU Orionis star (also FU Orionis object, or FUor) is a pre–main-sequence star which displays an extreme change in magnitude and spectral type. One example is the star V1057 Cyg, which became 6 magnitudes brighter and went from spectral type dKe to F-type supergiant during 1969-1970. These stars are named after their type-star, FU Orionis.

The current model developed primarily by Lee Hartmann and Scott Jay Kenyon associates the FU Orionis flare with abrupt mass transfer from an accretion disc onto a young, low mass T Tauri star. Mass accretion rates for these objects are estimated to be around 10−4 solar masses per year. The rise time of these eruptions is typically on the order of 1 year, but can be much longer. The lifetime of this high-accretion, high-luminosity phase is on the order of decades. However, even with such a relatively short timespan, as of 2015 no FU Orionis object had been observed shutting off. By comparing the number of FUor outbursts to the rate of star formation in the solar neighborhood, it is estimated that the average young star undergoes approximately 10–20 FUor eruptions over its lifetime.

The spectrum of FU Orionis stars are dominated by absorption features produced in the inner accretion disc. The spectrum of the inner part produce an spectrum of a F-G supergiant, while the outer parts and slightly colder parts of the disk produce a K-M type supergiant spectrum that can be observed in the near-infrared. In FU Orionis stars the disk radiation dominates, which can be used to study the inner parts of the disk.>>
Art Neuendorffer

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