Tag Archives: Inouye

Inouye Solar Telescope Reveals Unmatched Detail in Coronal Flare Loop

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Astronomers utilizing a visible broadband imager at NSF’s Daniel K. Inouye Solar Telescope captured an extraordinary coronal loop strand during the attenuation phase of the X1.3 class flare on August 8, 2024. This discovery heralds a significant advancement in determining the fundamental scale of solar coronal loops, advancing flare modeling into a groundbreaking territory.

High-resolution image of flares from the Inouye Solar Telescope, taken at 8:12 UT on August 2024. The image shows approximately four earth diamonds on each side. Labels for various related regions of the image are added to clarify: flare ribbons (bright regions of energy emissions in the dense low solar atmosphere) and arcades of coronal loops (arcs of magnetic field lines that transport energy from the corona to the flare ribbons). Image credit: NSF/NSO/AURA.

Coronal loops are plasma arches that follow solar magnetic field lines and often precede solar flares, which release massive amounts of energy tied to some of these lines.

This energy burst ignites solar storms that can impact Earth’s vital infrastructure.

Inouye astronomers observe sunlight at the H-Alpha wavelength (656.28 nm) to reveal specific solar features that remain hidden in other forms of solar observation.

“A lot of effort has gone into understanding this domain,” noted Dr. Cole Tamburi, an astronomer from the University of Colorado, Boulder.

“These flares represent some of the most energetic occurrences in our stars, and we were fortunate to capture this under ideal observational conditions.”

Dr. Tamburi and his team concentrated on the thin magnetic field loops resembling razors, woven over the flared ribbons.

On average, the loops measured around 48 km in width, although some results were limited by the telescope’s resolution.

“Before Inouye, I could only envision what this scale might look like,” remarked Dr. Tamburi.

“Now we can witness it in reality. These are the tiniest coronal loops observed on the sun.”

Inouye’s Visible Broadband Imager (VBI) tuned to the H-Alpha filter can resolve features down to 24 km.

This resolution is more than twice as sharp as that of the next best solar telescope, making this discovery possible.

“It’s one thing to theorize about a telescope’s capabilities,” commented Dr. Maria Kazachenko, PhD, from the University of Colorado Boulder.

“It’s invigorating to see those theories validated in practice.”

Initially, the research plan involved investigating the dynamics of chromospheric spectral lines using Inouye’s Visible Spectrometer (VISP). However, VBI data uncovered an unexpected treasure: an intricate coronal structure that can directly enhance flare models built with complex radiative hydrodynamic codes.

“We set out to find one thing and stumbled upon something even more intriguing,” Dr. Kazachenko stated.

The prevailing theory suggested that coronal loops could range from 10 to 100 km in width, but verifying this observationally had been challenging.

“We are finally gaining insight into the spatial scales we have long speculated about,” Dr. Tamburi explained.

“This paves the way for examining not just size, but shape, evolution, and even the scales where magnetic reconnection—the engine behind flares—occurs.”

Perhaps the most exciting implication is that these loops might be fundamental structures, core components of flare architecture.

“In that scenario, we wouldn’t just be mapping out clusters of loops; for the first time, we’re analyzing individual loops,” Dr. Tamburi added.

“It’s akin to observing a forest and suddenly recognizing all the trees.”

The image itself is stunning. A radiant arcade crowned with dark, thread-like loops, vibrant flared ribbons marked with strikingly sharp contours—ascending triangular patterns near the center and arc-shaped formations at the top.

“Even casual observers will soon recognize its complexity,” Dr. Tamburi remarked.

“This represents a landmark moment in solar science.”

“We are finally observing the sun at a scale that makes sense.”

The team’s paper will be published in Astrophysics Journal Letters.

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Cole A. Tumburi et al. 2025. Revealing unprecedented microstructure in coronal flare loops using DKIST. apjl in press; doi: 10.3847/2041-8213/ADF95E

Source: www.sci.news

First Detailed Map of Solar Coronal Magnetic Field Created by Inouye Solar Telescope

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This groundbreaking achievement will improve our understanding of the Sun’s atmosphere and shed light on how its changing conditions affect our technology-dependent society.

The Inouye Solar Telescope has released the first map of the magnetic field signal in the solar corona measured using the Zeeman effect. Image courtesy of NSF/NSO/AURA/NASA’s Solar Dynamics Observatory.

The Earth’s magnetic field protects us from the solar wind, protects our atmosphere and makes life possible.

But electromagnetic fields and high-energy particles from extreme solar activity could disrupt satellites, power grids, and other systems necessary for an increasingly technological society.

Understanding these dynamic interactions, which change on timescales ranging from days to centuries, is crucial to safeguarding our infrastructure and current ways of life.

Measuring the magnetic properties of the Sun’s corona, or outer atmosphere, has long challenged astronomers and the limits of technology.

today, Daniel K. Inouye Solar TelescopeLocated near the summit of Haleakala on the Hawaiian island of Maui, the facility is a state-of-the-art facility designed to study coronas.

The satellite has produced the first and most detailed map of the coronal magnetic field to date, taking an important first step in solving these mysteries.

“Inoue’s achievements in mapping the Sun’s coronal magnetic field are a testament to the innovative design and capabilities of this pioneering and unique observatory,” said Dr. Tom Shad, NSF National Solar Observatory investigator.

“This groundbreaking discovery is expected to greatly improve our understanding of the Sun’s atmosphere and its impact on the solar system.”

The researchers used the Zeeman effect, which measures magnetic properties by observing the splitting of spectral lines, to create a detailed map of the magnetic field of the solar corona.

“Spectral lines are distinct lines that appear at particular wavelengths in the electromagnetic spectrum and represent light absorbed or emitted by atoms and molecules,” they explained.

“These lines are unique to each atom and molecule and act like a fingerprint. By looking at the spectrum, scientists can determine the chemical composition and physical properties of an object.”

“When exposed to a magnetic field like the Sun’s, these lines split apart, giving us insight into the magnetic properties of the object.”

Previous attempts to detect such signals, last reported 20 years ago, have lacked the detail and regularity needed for widespread scientific investigation.

Now, Inouye’s unparalleled capabilities make it possible to study these important signals in detail and on a regular basis.

The solar corona can usually only be seen during a total solar eclipse, when most of the Sun’s light is blocked and Earth’s sky becomes dark.

But the Inouye Telescope uses a technique called coronagraphy to create an artificial eclipse that allows it to detect extremely faint polarized signals, highlighting its unparalleled sensitivity and cementing its status as a unique window into viewing our home star.

This telescope is Cryogenic near-infrared spectropolarimeter (Cryo-NIRSP) is one of the telescope’s main instruments used to study the corona and map its magnetic field.

“Just as detailed maps of the Earth’s surface and atmosphere have improved the accuracy of weather forecasts, this remarkably complete map of the magnetic field of the Sun’s corona will help us more accurately predict solar storms and space weather,” said Dr. Carrie Black, program director for NSF’s National Solar Observatory.

“The invisible yet incredibly powerful forces captured in this map will continue to drive solar physics for the next century and beyond.”

“Mapping the strength of the corona’s magnetic field is a fundamental scientific advance not only for solar research but for astronomy in general,” said Dr. Christoph Keller, director of the National Solar Observatory.

“This marks the beginning of a new era in understanding how stars’ magnetic fields affect planets in our solar system and the thousands of exoplanetary systems currently known.”

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This article has been edited from an original release by the National Solar Observatory.

Source: www.sci.news