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Topic Name: Princeton Scientist found A dwarf star with a surprisingly magnetic personality
Category: STAR (Space, Telecommunications & Radioscience)
Research persons: Dr. Edo Berger
Location: Princeton University, United States
Details
A dwarf star with a surprisingly magnetic personality and a huge hot spot
covering half its surface area is showing astronomers that life as a cool dwarf
is not necessarily as simple and quiet as they once assumed.
Simultaneous observations made by four of the most powerful Earth- and
space-based telescopes revealed an unusually active magnetic field on the
ultracool low-mass star TVLM513-46546. A team of astronomers, led by Dr. Edo
Berger, a Carnegie-Princeton postdoctoral fellow at Princeton
University, is using these observations to explain the flamboyant activity
of this M-type dwarf that lies about 35 light-years away in the constellation Boötes.
The team’s observations of TVLM513-46546 combine radio data from the Very
Large Array, optical spectra from the Gemini
North 8-meter telescope, ultraviolet images from the orbiting Swift
observatory and x-ray data from NASA’s
Chandra X-ray Observatory. This is the first time that such a powerful set
of telescopes has been trained on one of the smallest known stars. The study is
part of a program that looks at the origins of magnetic fields in ultracool
dwarfs, stars that astronomers always assumed were simple, quiet, and more
tranquil than their hotter and more massive siblings.
“With such a unique set of observations you always expect to find the
unexpected,” said Berger, “but we were shocked at the level of complexity
that this object exhibits.”
The star’s steady radio emission is interrupted with spectacular fireworks
displays of minute-long flares. These flares come from the catastrophic
collisions and merging of the magnetic fields in the corona of the star; these
actions drive the annihilation of magnetic energy like a giant short-circuits in
the fields. The team also observed soft x-ray emission and an x-ray flare.
Also for the first time, the group charted optical hydrogen-alpha emission
with a period of two hours that matches the two-hour rotation period of the
star. “We find a hot spot that covers half of the surface of the star like a
giant lighthouse that rotates in and out of our field of view,” said Berger.
“We still do not know why only half of the star is lit up in hydrogen and if
this situation remains unchanged over days, weeks, years, or centuries.”
Berger describes the dwarf star’s magnetic field as probably being a simple
dipole (north-south orientation, like the Earth’s much weaker magnetic field)
that extends out at least one stellar radius above the surface. There is also a
smaller-scale field that has loops similar to those seen on the Sun, but
smaller. “Those loops and arcs occur on random places on the surface of the
star, “said Berger. “That’s where the flares originate that last only a
few minutes, whereas the overall field doesn’t get disturbed.”
Objects like TVLM513-46546 were once thought to be models of stellar
quiescence and simplicity, with little to no magnetic field activity. “Theory
has always said that as we look at cooler and cooler stars, the coolest will be
essentially dead,” said Berger. “It turns out that stars like TVLM513-46546
have very complex magnetic activity around them, activity more like our Sun than
that of a star that is barely functional.”
This one’s complicated magnetic field environment and possible hot spot may
indicate some unusual activity beneath the star’s surface (in its dynamo) or
possibly even the existence of a still-hidden companion. The idea of an unseen
companion as an explanation for the star’s excitable magnetic disposition is
an intriguing one, says Berger, but no such object has yet been detected. “The
main idea to consider here is an analogy to other systems where the presence of
a companion directly or indirectly excites magnetic activity,” he said.
Like other ultracool dwarf stars, TVLM513-46546 is an M-type star with
surface temperatures below about 2400K (2127 Celsius) and a mass of only 8 to
10% that of our Sun. By contrast, the Sun is a G-type star with an average
surface temperature of 6000K (5727 Celsius).
Imagine the interior of the Sun layered like an onion. Its internal
convection is the process by which heat from the nuclear fusion at the core is
transported by large spinning currents that move through the Sun’s outer
layers. Differential rotation is simply the term for the different spin rates of
different layers. Together these motions of electrically charged gas spin up the
magnetic field structures we see at the Sun.
By contrast, an ultracool M-type star like TVLM513-46546 is fully convective.
That is, the zone that transports heat to the surface of the star extends all
the way from the stellar surface into the center, like the bubble of a huge
boiling pot. Such a simple structure has been predicted to generate a very basic
magnetic field structure, perhaps more like the Earth’s than the complex
fields we see on the Sun. Why TVLM513-46546 has such a complex field and
activity remains to be studied.
In order to find out if this star is just a stellar oddity, or if it might
turn out be a typical prototype of ultracool dwarfs, the research team plans to
continue with observations of other such stars. The team expects the larger
sample to show how other candidate low-mass stars (and brown dwarfs, objects too
hot to be planets and too cool to be stars) generate magnetic fields. Berger
also notes that he’d like to get more observations to try and spot any
possible companions to such stars. “The issue of a possible companion is
really pure speculation at this point,” he said. “However, I am trying to
get observations that will assess this possibility.”
These results are being published in the February 10, 2008 issue of the Astrophysical
Journal. A preprint of the paper can be found here.
Partial studies of magnetic activity on these types of stars have been
performed previously, but this is the first time that such a powerful set of
telescopes has been simultaneously pointed at the same object.
Note for Magnetic field
In physics, the magnetic field is a field that permeates space and which exerts a magnetic force on moving electric charges and magnetic dipoles. Magnetic fields surround electric currents, magnetic dipoles, and changing electric fields.
When placed in a magnetic field, magnetic dipoles align their axes to be parallel with the field lines, as can be seen when iron filings are in the presence of a magnet. Magnetic fields also have their own energy and momentum, with an energy density proportional to the square of the field intensity. The magnetic field is measured in the units of teslas (SI units) or gauss (cgs units).
There are some notable specific incarnations of the magnetic field. For the physics of magnetic materials, see magnetism and magnet, and more specifically ferromagnetism, paramagnetism, and diamagnetism. For constant magnetic fields, such as are generated by stationary dipoles and steady currents, see magnetostatics. For magnetic fields created by changing electric fields, see electromagnetism.
The electric field and the magnetic field are components of the electromagnetic field.
About Researcher
Dr. Edo
Berger
In figure 1, Top: Time series of Hydrogen-alpha observations from the Gemini North telescope showing the periodic signal that results from a hot spot covering half of the surface of TVLM 513-46546. The high points are when the hot spot faces Earth, and the low points are when the hot spot is on the far side of the star. Bottom: Time series of radio emission from observed with the Very Large Array. The minute-long flares are clearly visible.
In figure 2, Artist’s rendition of what the magnetic fields and surface might look like on TVLM513-46546. Note that the hot-spot that is estimated to cover up to 50% of the surface area of the star is oriented to the left of the star and is not entirely visible in this orientation.
 
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