Astronomers observe huge flares on a young brown dwarf

Astronomers observe huge flares on a young brown dwarf
The strongest superflare observed on CFHT-BD-Tau 4. The blue dots represent the observed data. The dashed vertical lines represent the start and end times of flare. Credit: Paudel et al., 2018.

Using Kepler, astronomers have spotted two superflares on a very young brown dwarf known as CFHT-BD-Tau 4. The two superflares turn out to be the strongest flares observed on any brown dwarf so far. The finding is detailed in a paper published May 28 on the arXiv pre-print server.

NASA's exoplanet-hunting Kepler spacecraft lost its two reaction wheels in 2013, and the satellite was repurposed under the K2 mission to perform high-precision photometry of selected fields in the ecliptic. The revived space telescope is still an essential tool for astronomers studying stars and planets beyond our solar system.

During its Campaign 13, taking place between March 8 and May 27, 2017, K2 was used to observe a filed on the sky, which included the Taurus-Auriga star-forming region. Data from this observational campaign allowed a team of astronomers led by Rishi R. Paudel of the University of Delaware, to identify two huge flares on a brown dwarf CFHT-BD-Tau 4 located in this region of star formation.

With an estimated age of around 1 million years, CFHT-BD-Tau 4 (also known as 2MASS J04394748+2601407) was classified as a young brown dwarf of spectral type M7 at a distance of about 480 light years from the Earth. It has a radius of about 0.65 solar radii, mass of approximately 0.064 solar masses and an effective temperature of 2,900 K.

Paudel's team analyzed the flares on CFHT-BD-Tau 4, which resulted in important insights about flaring activity of this brown dwarf.

"We present photometric measurements of two superflares observed on a very young brown dwarf CFHT-BD-Tau 4, observed during Campaign 13 of the Kepler K2 mission," the researchers wrote in the paper.

According to the study, the stronger of the two observed flares, which lasted almost two days, brightened by a factor of about 48 relative to the quiescent photospheric level and had an estimated total bolometric energy up to 190 undecillion erg. Lasting nearly 10 hours, the weaker flare was found to be a complex (multipeaked) outburst that reached an estimated total bolometric energy of 4.7 undecillion erg.

The astronomers noted that the energies of the newly observed superflares are larger than these of the strongest flares reported on other young , namely 2M0335+2342 and CFHT-PL-17. Hence, the outbursts described in the paper are the strongest flares observed on any brown dwarf to date.

In concluding remarks, the researchers wrote that the superflares found by them will be very helpful to understand how such flares impact the dynamical and chemical evolution of planet-forming disks around low-mass stars and brown dwarfs.

The authors of the paper added that the flares on CFHT-BD-Tau 4 might be helpful in explaining the mysteries regarding the formation of the chondrules and the calcium-aluminium-rich inclusions, which need transient heat sources to melt the precursor material. They underlined that it is currently impossible to explain the formation of these materials in the context of thermodynamic equilibrium between the pre-main-sequence stars and the disks around them.


Explore further

Powerful flare detected on an M-dwarf star

More information: K2 Ultracool Dwarfs Survey. IV. Monster flares observed on the young brown dwarf CFHT-BD-Tau 4, arxiv.org/abs/1805.11185

Abstract
We present photometric measurements of two superflares observed on a very young brown dwarf CFHT-BD-Tau 4, observed during Campaign 13 of the textit{Kepler K2} mission. The stronger of the two superflares brightened by a factor of ∼48 relative to the quiescent photospheric level, with an increase in textit{Kepler} magnitude ΔKp~ = -4.20. It has an equivalent duration of ∼107 hour, a flare duration of 1.7 day, and an estimated total bolometric (ultraviolet/optical/infrared) energy up to 2.1 × 1038 erg. The weaker of the two superflares is a complex (multipeaked) flare with an estimated total bolometric (UV/optical/IR) energy up to 4.7 × 1036 erg. They are the strongest flares observed on any brown dwarf so far. The flare energies are strongly dependent on the value of visual extinction parameter AV used for extinction correction. If we apply a solar flare-model to interpret the two superflares, we find that the magnetic fields are required to be stronger by as much as an order of magnitude than previous reports of field measurements in CFHT-BD-Tau 4 by Reiners et al. (2009b). On the other hand, if we interpret our data in terms of accretion, we find that the requisite rate of accretion for the stronger superflare exceeds the rates which have been reported for other young brown dwarfs.

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Citation: Astronomers observe huge flares on a young brown dwarf (2018, June 6) retrieved 18 April 2019 from https://phys.org/news/2018-06-astronomers-huge-flares-young-brown.html
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User comments

Jun 06, 2018
What is actually being flared? I know next to nothing of brown dwarves so I wonder if their constituent layers have notably different compositions of materials. Either way, this is fascinating.

Jun 06, 2018
This comment has been removed by a moderator.

RNP
Jun 06, 2018
@ZoeBell
I understand your surprise, but such things have been detected before. The earliest discovery that I can find with a quick search is here;

https://science.n...12jul_1m

RNP
Jun 06, 2018
P.S. @ZoeBell
They are not "graves of larger exploding stars". They are simply objects whose masses lie between the largest planets and smallest stars (they emit significant energy, but due purely to a slow, steady gravitational contraction rather than a fusion process).

Jun 06, 2018
This comment has been removed by a moderator.

RNP
Jun 06, 2018
@ZoeBell
Most of your post makes no sense to me. So I will just make one point;
In "mainstream astrophysics" (as if there were any other) a "failed star" is just something of nearly stellar mass that "fails" to ignite fusion and thus only produces energy by its slow contraction under gravity.

Jun 06, 2018
This comment has been removed by a moderator.

RNP
Jun 06, 2018
@ZoeBall
You misunderstand me. In my view ANY idea, if sufficiently supported by evidence to make it feasible, is "mainstream science", even if I do not agree with the idea.

If you are one of the advocates of ideas that have NOT been supported by observation/evidence then your idea does not deserve to be considered science, but at best conjecture.

Jun 07, 2018
fff

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