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Could We Directly Observe Volcanoes on an Exoplanet?
After a few decades of simply finding exoplanets, humanity is starting to be able to do something more – peer into their atmospheres. The James Webb Space Telescope (JWST) has already started looking at the atmospheres of some larger exoplanets around brighter stars. But in many cases, scientists are still developing models that both explain what the planet’s atmosphere is made of and match the data. A new study from researchers at UC Riverside, NASA’s Goddard Spaceflight Center, American University, and the University of Maryland looks at what one particular atmospheric process might look like on an exoplanet – volcanism.
There are a few caveats in the paper, though. First, the model itself is for an “exoEarth” – a planet equivalent to Earth circling a Sun-like star. Even JWST isn’t powerful enough to capture the data spectrographic data of an atmospheric planet of this size, no matter how close it is. So, the authors make some assumptions about the next generation of large in-space telescopes – specifically, they refer to the LUVOIR project we’ve reported on before.
Assuming the next great space telescope can collect data as planned, it is still necessary to understand the data that comes in. In particular, understanding what the dips in spectra are caused by and what, if any, specific pattern emerges that might be related to active volcanoes.
Fraser talks about JWST’s capabilities as an exoplanet hunter.Those volcanoes would likely be spewing out sulfur dioxide and sulfate aerosols into the atmosphere of the exoEarth. To model the introduction of those materials, the authors turned to a simulation program called the Goddard Earth Observing System Chemistry Climate Model (GEOSCCM). This model allows researchers to manipulate certain aspects of the atmosphere and watch the results over long periods.
In this particular case, the researchers modeled the effect of a volcano by injecting one of several quantities of sulfur dioxide into the atmosphere every three months for four years. They then observed the effects for some time after the volcano stopped “erupting” (i.e., when they stopped injecting sulfur dioxide into the model) so they could conclude the atmospheric composition of a planet in recovery from a sustained eruption.
Three main spectra lines stood out in the researcher’s analysis. All three were related to oxygen – O2 (the breathable stuff), O3 (ozone), and good old H20. Each of these three spectral signals underwent serious changes around the time of the eruptions, and then those changes were reversed once the eruptions ceased.
Fraser talks about the difficulties in directly imaging planet with Dr. Thayne CurrieOne particular feature that stood out was the spectral line for ozone (O3). It continually decreased during the eruption phase, likely caused by its transformation into sulfuric acid. After the eruptions, however, the quantity of ozone in the modeled atmosphere began to creep up again, showing a similar resilience to our own ozone layer that had been impacted by the use of CFCs last century.
With their expected results in hand, the researchers calculated how long they thought it would take a telescope like LUVOIR to observe a particular exoplanet to find these tale-tell spectral lines that would indicate whether there was active volcanism on the planet. Ozone was relatively simple, as it required only 6 hours of observation. In contrast, water vapor was trickier to quantify, as it could be as short as 9 hours or impossible altogether, depending on the variability in the signal.
Studies like this will be crucial to the success of any future large space telescope mission, and there will be plenty of things for LUVOIR, or its equivalent, to look at when (and if) it launches. Therefore, plenty of other studies detailing what features we can expect to see will be necessary in the near future. But for now, at least we’ll know what to look for if we see volcanoes on a planet just like our own.
Learn More:
Ostberg et al – The Prospect of Detecting Volcanic Signatures on an ExoEarth Using Direct Imaging
UT – A Super-Earth (and Possible Earth-Sized) Exoplanet Found in the Habitable Zone
UT – Can JWST Tell the Difference Between an Exo-Earth and an Exo-Venus?
UT – Earth is an Exoplanet to Aliens. This is What They’d See
Lead Image:
LP 791-18 d, shown here in an artist’s concept, is an Earth-size world about 90 light-years away.
Credit: NASA’s Goddard Space Flight Center/Chris Smith (KRBwyle)
The post Could We Directly Observe Volcanoes on an Exoplanet? appeared first on Universe Today.
Scientists Pursue the Total Solar Eclipse with NASA Jet Planes
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Scientists Pursue the Total Solar Eclipse with NASA Jet PlanesThe April 8, 2024, total solar eclipse will produce stunning views across North America. While anyone along the eclipse path with a clear sky will see the spectacular event, the best view might be 50,000 feet in the air, aboard NASA’s WB-57 jet planes. That’s where a trio of NASA-funded teams are sending their scientific instruments to take measurements of the eclipse.
Two teams will image the Sun’s outer atmosphere – the corona – and a third will measure the ionosphere, the upper electrically charged layer of Earth’s atmosphere. This information will help scientists better understand the structure and temperature of the corona, the effects of the Sun on Earth’s atmosphere, and even aid in the search of asteroids that may orbit near the Sun.
The April 8, 2024 total solar eclipse will produce stunning views across North America. While anyone along the eclipse path with a clear sky will see the spectacular event, the best view might be 50,000 feet in the air, aboard NASA’s WB-57 jet planes. That’s where a trio of NASA-funded teams are sending their scientific instruments to take measurements of the eclipse. Credit: NASADuring a total solar eclipse, the Moon perfectly blocks the bright face of the Sun, casting a small swath of Earth in darkness. With the Sun’s main light masked, the much dimmer solar corona becomes visible to the naked eye. This provides scientists a unique opportunity to study this mysterious region of the Sun. The brief blocking of sunlight also allows scientists to study how the Sun’s light affects Earth’s atmosphere.
In the past, solar eclipses have driven numerous scientific discoveries. For this solar eclipse, NASA is funding several scientific experiments – including the three using the WB-57s – to make measurements during the eclipse. NASA’s WB-57s fly much higher than commercial aircraft. This altitude allows the jets to fly above clouds – meaning no chance of missing the eclipse due to bad weather. Additionally, the height puts the jets above most of Earth’s atmosphere, which allows for the cameras to take crisper images and capture wavelengths, such as infrared light, that don’t make it to the ground. Since the planes can travel at 460 miles per hour, they’re also able to extend the time they spend in the Moon’s shadow. While the eclipse will last no more than four and a half minutes at any point on the ground, the planes will see an eclipse that lasts about 25 percent longer, over 6 minutes and 22 seconds.
This map shows the path of the 2024 total solar eclipse. The dark path across the continent is the path of totality. By flying along this path, the WB-57s will extend the amount of time they spend in totality.NASA/Scientific Visualization Studio/Michala Garrison; Eclipse Calculations By Ernie Wright, NASA Goddard Space Flight Center“By extending the duration of totality, we’re increasing the duration of how much data we can acquire,” said Shadia Habbal, a researcher at the University of Hawaii who leads of one of the WB-57 eclipse experiments.
Habbal’s experiment will fly spectrometers – which record specific wavelengths of light and cameras. The instruments will measure the temperature and chemical composition of the corona and coronal mass ejections, which are large bursts of solar material. With this data, scientists aim to better understand the structure of the corona and identify the source of the solar wind, the constant stream of particles emitted by the Sun.
Habbal hopes the results of their study will help differentiate between different competing models of how the corona is heated. “This light is our best probe short of sticking a thermometer in the corona,” Habbal said.
NASA/ESA’s Solar and Heliospheric Observatory (SOHO) captured this video of a coronal mass ejection on March 13, 2023. NASA/ESA/SOHOFor another team, led by Amir Caspi at the Southwest Research Institute in Boulder, Colorado, it’s not their first time chasing eclipses by plane. Caspi led a previous trailblazing experiment with the WB-57s during the 2017 total solar eclipse that crossed America from sea to sea. Images taken from the jet were used to study the structure of the corona.
That time was the first the jets had ever been used to study an eclipse. This time, an improved camera setup will allow measurements in more wavelengths from infrared to visible light that will hopefully reveal new information about structures in the middle and lower corona. The observations, taken with a high-resolution, high-speed camera, could also help study a dust ring that circles the Sun and help search for asteroids that may orbit near the Sun.
“There isn’t a lot of data of the Sun at some of the wavelengths we’ll be studying,” Caspi said. “We don’t know what we’ll find, so it’s extra exciting to be making these measurements.”
A third experiment will study the effects of the Moon’s shadow on the ionosphere using an instrument called an ionosonde, which was designed at JHU APL. An ionosonde functions like a simple radar. The device sends out high-frequency radio signals and listens for their echoes rebounding off the ionosphere, which allows the researchers to measure how charged the ionosphere is.
“The eclipse basically serves as a controlled experiment,” said Bharat Kunduri, leader of the ionosphere project and a research assistant professor at Virginia Tech in Blacksburg, Virginia. “It gives us an opportunity to understand how changes in solar radiation can impact the ionosphere, which can in turn impact some of these technologies like radar and GPS that we rely on in our daily lives.”
By Mara Johnson-Groh
NASA’s Goddard Space Flight Center, Greenbelt, Md.
A spectacular eclipse will sweep across North America on April 8, 2024! Enjoy these free…
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