It started a few years ago. Shultz was minding his astronomy at UD
and Paolo Leto, a researcher at the Catania Astrophysical Observatory,
was doing the same in Italy. Both were studying magnetic massive stars —
a rare variety of bright, hot stars with magnetic fields thousands of
times stronger than the sun’s. These stars are emerging as promising
laboratories for studying plasmas under extreme conditions, Shultz said.
“Like the sun, massive stars have stellar winds — constant outflows
of charged particles,” he said. “Because the wind is a plasma — a gas of
charged particles — it responds to a magnetic field.”
That creates a magnetosphere, which all stars and planets with
magnetic fields — including Earth — have. Some are complex, as our sun’s
magnetosphere is. Others are more stable, as the magnetospheres around
these rare stars are.
Working independently, Shultz and Leto came to the same surprising
conclusion — that the rotation speed of these stars is closely related
to how bright they are at radio wavelengths.
Rotation speed wasn’t part of the previous model. But as they
collected data from all of the previous studies they could find,
assembling a large sample of these magnetic stars — 131 of them — they confirmed that rotation speed is a critical factor.
With the help of Owocki, a theoretical astrophysicist, they were also
able to identify a plausible source of energy driving the powerful
radio emissions of these stars.
Owocki showed
that the connection between rotation and radio observations is
consistent with what happens in centrifugal breakout events. Breakout
occurs in the magnetospheres of fast-rotating stars. The plasma, which
can move at thousands of kilometers per second, is subject to extreme
centrifugal forces. It is held in place by the magnetic field, but as
the wind feeds more plasma into the magnetosphere it eventually
overpowers that restraint, bursting free and erupting into interstellar
space. During the breakout, the magnetic field reconnects, releasing an
enormous amount of energy and accelerating electrons to the high
velocities needed to generate radio waves.
Twinkle, twinkle, indeed.
“We now know there is a close relationship with magnetic field
strength and the rotation and thanks to Stan’s theoretical work, the
real breakthrough is that we were able to tie this to the centrifugal
breakout mechanism,” Shultz said.
Centrifugal breakout had been predicted more than a decade earlier in
simulations performed by Asif ud-Doula, who was a student of Owocki’s,
earned his doctorate in 2002 and now is an associate professor at Penn
State-Scranton.
These kinds of magnetic-field dynamics are similar to processes
within Earth’s magnetosphere which can affect space weather. Space
weather can have real consequences for humans, as Elon Musk’s team
experienced in February, when dozens of SpaceX satellites were yanked
out of orbit by a massive geomagnetic storm, re-entered the Earth's
atmosphere and burned up.
With multiple companies — including SpaceX — planning to launch new
satellites and expand internet access around the world, understanding
these dynamics and learning how to cope with them is crucial.
The discovery may also enhance our ability to find planets around
other stars that we cannot otherwise detect now. Leto showed that the
relationship between rotation and radio brightness is consistent with
the radio emission of Jupiter, suggesting that the same mechanisms might
be at work within the magnetospheres of other planets as well as much
cooler stars.
The Royal Astronomical Society published complementary articles from both angles, with Shultz and Leto presenting the observations and experimental data and Owocki and team explaining how centrifugal breakout events would provide all the energy needed for such phenomena.
Including rotation speed in calculations makes it possible to more
accurately predict the radio brightness of the star, Shultz said.
“If you know just three things — the size of the star, the strength
of its magnetic field and how fast it’s rotating — you can predict how
bright it will be,” Shultz said.
Finding the rotational velocity and the size of the star are fairly
easy measurements (for an astronomer). Measuring the strength of the
magnetic field is trickier, because the measurement relies on a subtle
quantum mechanical phenomenon (known as the Zeeman effect), which is
very difficult to detect.
“You need a big telescope and a lot of time on that telescope,” Shultz said.
Using a new kind of measurement tool that includes the rotational
velocity can help. Plugging that into a calculation that includes the
star’s radio luminosity, the distance to the star and its radius may
help scientists determine the magnetic field strength indirectly.
And because of the stability of these stars, observations here can
help scientists understand these dynamics in more turbulent
environments.
“What is nice about this result, is that it gives you a laboratory
where you know exactly what’s causing the magnetic fields to stretch and
reconnect,” Owocki said. “It’s not an isolated result. There are
implications of how you could use it in different areas.”
Another UD-affiliated researcher contributed to this work — Barnali
Das, a postdoctoral researcher from India who works with UD Associate
Professor Veronique Petit.
Das said that although these results were drawn from hot stars, they can apply in other contexts.
“This is also applicable for very cool objects, going down to very
cool stars,” she said. “It demonstrates how we can use this. I think
this is the first time it becomes evident that research in the field of
magnetic massive stars has application over a much broader field, such
as searching for the magnetic fields of exoplanets.”
The previous model used to explain the energy behind radio emissions
from hot stars was generated by “current sheets” — the place at the
equator of a magnetic field where the polarity changes from north to
south or from south to north. The magnetic field becomes weaker as it
moves away from the star while the wind grows stronger, eventually
pushing through the magnetic field.
“The problem with that paradigm is that rotation plays no role in it,” Shultz said. “It turns out not to be the case at all.”
Even when radio emission from magnetic stars was first discovered in
1987, researchers suspected that rotation should play a role in the
phenomenon, Shultz said, and while they looked for it they did not have
rotation data on enough stars at that time.
Many more observations are needed to further confirm these findings and how they apply in other contexts.
“As new telescopes come online, this work will give ideas of targets to look for,” Owocki said.
And our understanding will expand and evolve, as the scientific method is applied.
“None of our truths are absolute,” Owocki said. “This theory could
fall apart. If an idea you have doesn’t work, you don’t want to make a
square peg fit into a round hole. You abandon that and move on to what
does work.”
Owocki said he draws energy and insight from these collaborative projects.
“What I really love is how interactive it is with other people,” he
said. “I learn from students and postdocs. Even if you’re an expert on
one thing, not on all the other stuff, having collaborators who can tell
you about this and that — a collaboration that goes on to push the ball
ahead — that’s what I find most rewarding.”
Other collaborators also included researchers from the National
Research Council of Canada, Howard University in Washington D.C., NASA,
the National Centre for Radio Astrophysics at Pune, India; the
University of Moncton in New Brunswick, Canada, Uppsala University in
Sweden, the Armagh Observatory and Planetarium in the United Kingdom,
the University of Western Ontario, Canada; Paris Observatory in France;
the European Organization for Astronomical Research in Santiago, Chile;
and the Royal Military College of Canada.
This work was supported by the Annie Jump Cannon Fellowship, NASA and India’s Department of Atomic Energy.