The NSF Daniel K. Inouye Solar Telescope
presents its first map of the solar coronal magnetic field signals as measured
using the Zeeman Effect. The Zeeman Effect polarizes the coronal emission,
which requires the advancements of the Inouye Solar Telescope to measure as its
signals are only a few parts per billion of the sun's surface brightness. The
background image identifies the region observed in detail by Inouye as imaged
by NASA's Solar Dynamics Observatory in ultraviolet light. Credit: NSF/NSO/AURA
The Daniel K. Inouye Solar
Telescope, the world's most powerful solar telescope, operated by the NSF
National Solar Observatory (NSO), achieved a major breakthrough in solar
physics by successfully producing its first detailed maps of the sun's coronal
magnetic fields.
This milestone, led by NSO
Associate Astronomer Dr. Tom Schad, was published in Science Advances, and promises to
enhance our understanding of the sun's atmosphere and how its changing
conditions lead to impacts on Earth's technology-dependent society.
The corona, or the sun's outer
atmosphere, greatly influences solar winds and space weather events like solar flares and coronal mass ejections. However, the magnetic forces that drive these events and the corona are challenging to measure.
The telescope directly mapped the
strength of the magnetic field in the solar corona, the outer part of the solar atmosphere that can be
seen during a total eclipse. This breakthrough promises to enhance our
understanding of space weather and its impact on Earth's technology-dependent
society.
The corona: The launch pad of space weather
The sun's magnetic field generates regions in the sun's atmosphere, often rooted by sunspots,
that store vast amounts of energy that fuel explosive solar storms and drive
space weather.
The corona, the sun's outer
atmosphere, is a superheated realm where these magnetic mysteries unfold.
Mapping coronal magnetic fields is essential to understanding and predicting
space weather—and to protect our technology in Earth and space.
Why it matters
Earth's magnetic field shields us
from solar winds, protecting our atmosphere, and making life possible. However,
the electromagnetic fields and energetic particles from extreme solar eruptions
can disrupt satellites, power grids, and other systems we need in our
increasingly technological society.
Understanding these dynamic
interactions, which change on timescales ranging from days to centuries, is
crucial for safeguarding our infrastructure and current way of life.
Measuring the corona's magnetic properties has long challenged astronomers and the limits of technology. Today, the Inouye Solar Telescope is the most advanced facility designed to study the corona, and has made a crucial first step in resolving these mysteries by producing its first coronal magnetic field maps—the most detailed to date.
The NSF Daniel K. Inouye Solar Telescope presents
its first map of the solar coronal magnetic field signals as measured using the
Zeeman Effect. The Zeeman Effect polarizes the coronal emission, which requires
the advancements of the Inouye to measure as its signals are only a few parts
per billion of the sun's surface brightness. Credit: NSF/NSO/AURA
The Inouye Solar Telescope's first maps of the
corona's magnetic field
Since the
1950s, solar physicists have mapped the magnetic fields on the sun's surface,
providing valuable insights. However, maps of the magnetic field in the zones
above the surface, like the corona, have long been sought as it is in these
locations that solar storms originate. The Inouye, located near the summit of
Maui's Haleakalā in Hawai'i, now provides the capabilities to meet this
critical need.
The Inouye has
created its first detailed magnetic field maps of the solar corona using the
Zeeman Effect, which measures magnetic properties by observing spectral
line splitting. Spectral lines are distinct lines that appear
at specific wavelengths in the electromagnetic spectrum, representing the light
absorbed or emitted by atoms or molecules.
These lines
act like "fingerprints," as they are unique to each atom or molecule,
allowing scientists to identify the chemical composition and physical
properties of celestial objects by looking at their spectra. When exposed to a
magnetic field, like in the sun, these lines split, which gives us an insight
into the object's magnetic properties.
Previous
attempts at detecting these signals, last reported two decades ago, lacked the detail
and regularity needed for extensive scientific investigation. Today, the
Inouye's unmatched capabilities allow for detailed, regular studies of these
crucial signals.
Technological marvel
Typically, one
can only view the sun's corona—a region one million times fainter than the
solar disk—during a total solar eclipse, when most of the sun's light is
blocked and Earth's sky goes dark.
The Inouye,
however, uses a technique called coronagraphy to create artificial eclipses,
allowing it to detect extremely faint polarized signals—a billion times fainter
than the solar disk—highlighting its unparalleled sensitivity and solidifying
its status as a unique window to our home star.
The Inouye accomplishes this with its Cryogenic Near-Infrared Spectropolarimeter (Cryo-NIRSP), one of the telescope's primary instruments used to study the corona and map its magnetic fields. This instrument was designed and built by the University of Hawai'i Institute for Astronomy.
The NSF Daniel K. Inouye Solar Telescope extends
our abilities to understand the physics of the solar corona. This animation
first shows the evolving solar surface, as routinely imaged by NASA's Solar
Dynamics Observatory. Here, the temperatures are about 6000 degrees Celsius. A
map of the surface magnetic fields follows, where one can notice concentrated
regions of magnetism (black and white regions). That magnetic field extends in
three dimensions upwards where the solar corona forms, creating bright hot gas
at millions of degrees. The Inouye is now able to map the magnetic fields in
the coronal itself, which provides critical insight into how the corona heating
and the entrapment and release of magnetic energy occurs. Credit: NSF/NSO/AURA
"The Inouye's achievement in
mapping the sun's coronal magnetic fields is a testament to the innovative
design and capabilities of this trailblazing unique observatory," said Tom
Schad, scientist at NSO, and first author of the study. "This breakthrough
promises to significantly enhance our understanding of the solar atmosphere and
its influence on our solar system."
Future prospects
This milestone marks the beginning
of a new era in solar physics. The Inouye's success in mapping the sun's coronal
magnetic fields reaffirms its vision and mission, and opens new frontiers in
understanding the sun's influence on space weather.
"Just as detailed maps of the
Earth's surface and atmosphere have enabled more accurate weather prediction,
this thrillingly complete map of the magnetic fields in the sun's corona will
help us better predict solar storms and space weather," says Dr. Carrie
Black, NSF program director for the NSO.
"The invisible yet
phenomenally powerful forces captured in this map will propel solar physics
through the next century and beyond."
Christoph Keller, NSO Director,
said, "Mapping the strength of the magnetic field in the corona is a
fundamental scientific breakthrough, not just for solar research, but for
astronomy in general."
"This is the beginning of a
new era where we will understand how the magnetic fields of stars affect
planets, here in our own solar system and in the thousands of exoplanetary
systems that we now know about."
Ongoing and future studies will refine diagnostic tools and techniques, leading to deeper insights into the sun's magnetic environment and its impact on Earth and our solar system.
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