Astronomy

gizmodo.com

Astronomers imaging the cosmos with the Webb Space Telescope have found the most distant active supermassive black hole yet. The black hole was “seen” as it was around 570 million years after the Big Bang.

The universe is about 13.77 billion years old, meaning the newly discovered black hole popped up when the universe was just over 4% its current age. The black hole lurks within the galaxy CEERS 1019, and at nine million solar masses, is the least massive of any supermassive black hole yet seen in the early universe.

For comparison, the black hole at the center of the Milky Way—Sagittarius A*—is less than five million solar masses. Supermassive black holes are some of the densest objects in the universe and can be billions of times the mass of our Sun. Like all black holes, they have such intense gravitational fields that not even light can escape their event horizons, leaving astronomers to image the “shadow” in which the black hole resides.

CEERS 1019’s black hole was spotted by a research team conducting the Cosmic Evolution Early Release Science Survey, or CEERS. The survey takes deep field images of the cosmos, which cover sweeping swaths of the sky and peer deeply into them, allowing scientists to see some of the universe’s most ancient light.

The newest CEERS mosaic image is 510 megabytes—beyond what this website can handle—so if you’d like to peruse the cosmos in all its digitized glory you can download the full-size image here. The combined image contains about 100,000 galaxies.

Besides CEERS 1019, the survey team spotted eleven galaxies that date to when the universe was between 470 million years old and 675 million years old, and two other black holes dating to around one billion years after the Big Bang, according to a Space Telescope Science Institute release.

Four papers on CEERS Survey data are set to publish in The Astrophysical Journal Letters. The papers announce the discovery of the ancient black hole, detail the spectroscopy of active galactic nuclei at high redshifts, the confirmation of distant galaxies, and an initial characterization of their properties.

“Looking at this distant object [CEERS 1019] with this telescope is a lot like looking at data from black holes that exist in galaxies near our own,” said Rebecca Larson, an astronomer at the University of Texas at Austin and lead author of one of the CEERS papers, in the STScI release. According to the release, Webb is detecting more galaxies at these extreme distances than researchers expected it would.

Black hole evolution is still something of a black box in astrophysics, so being able to see such ancient black holes is a boon to researchers trying to understand how the universe’s most massive objects grow and affect masses around them.

The CEERS Survey is providing data that will help scientists decipher black holes, just as gravitational wave observatory data is clueing astrophysicists into the gravitational wave background generated by supermassive black holes.

But supermassive black holes have to grow out of something, and a dearth of intermediate-mass black holes in the cosmos has only raised more questions about how stellar-mass black holes give rise to such cosmic behemoths.

“Researchers have long known that there must be lower mass black holes in the early universe. Webb is the first observatory that can capture them so clearly,” said Dale Kocevski, an astronomer at Colby College and lead author of another CEERS paper, in the same release. “Now we think that lower mass black holes might be all over the place, waiting to be discovered.”

Next week will mark a year of Webb Space Telescope science observations; in other words, the trove of insights are just the beginning for the powerful observatory.

Starlink doesn't just interfere with optical astronomy, it also interferes with radioastronomy.

It may also explain why the corona is SO much hotter than the rest of the Sun's atmosphere 🧐

Be gentle, this is my first post 😬

Interactive: https://www.mapoftheuniverse.net

cross-posted from: https://mander.xyz/post/989527

By Pablo Carlos Budassi

gizmodo.com

The search for planets outside our Solar System – exoplanets – is one of the most rapidly growing fields in astronomy. Over the past few decades, more than 5,000 exoplanets have been detected and astronomers now estimate that on average there is at least one planet per star in our galaxy.

What Is Planet Nine and Why Can’t We Find It?

Many current research efforts aim at detecting Earth-like planets suitable for life. These endeavours focus on so-called “main sequence” stars like our Sun – stars which are powered by fusing hydrogen atoms into helium in their cores, and remain stable for billions of years. More than 90% of all known exoplanets so far have been detected around main-sequence stars.

As part of an international team of astronomers, we studied a star that looks much like our Sun will in billions of years’ time, and found it has a planet which by all rights it should have devoured. In research published today in Nature, we lay out the puzzle of this planet’s existence – and propose some possible solutions.

A glimpse into our future: red giant stars

Just like humans, stars undergo changes as they age. Once a star has used up all its hydrogen in the core, the core of the star shrinks and the outer envelope expands as the star cools.

In this “red giant” phase of evolution, stars can grow to more than 100 times their original size. When this happens to our Sun, in about 5 billion years, we expect it will grow so large it will engulf Mercury, Venus, and possibly Earth.

Eventually, the core becomes hot enough for the star to begin fusing helium. At this stage the star shrinks back to about 10 times its original size, and continues stable burning for tens of millions of years.

We know of hundreds of planets orbiting red giant stars. One of these is called 8 Ursae Minoris b, a planet with around the mass of Jupiter in an orbit that keeps it only about half as far from its star as Earth is from the Sun.

The planet was discovered in 2015 by a team of Korean astronomers using the “Doppler wobble” technique, which measures the gravitational pull of the planet on the star. In 2019, the International Astronomical Union dubbed the star Baekdu and the planet Halla, after the tallest mountains on the Korean peninsula.

A planet that should not be there

Analysis of new data about Baekdu collected by NASA’s Transiting Exoplanet Survey Satellite (TESS) space telescope has yielded a surprising discovery. Unlike other red giants we have found hosting exoplanets on close-in orbits, Baekdu has already started fusing helium in its core.

Using the techniques of asteroseismology, which studies waves inside stars, we can determine what material a star is burning. For Baekdu, the frequencies of the waves unambiguously showed it has commenced burning helium in its core.

Sound waves inside a star can be used to determine whether it is burning helium.

Sound waves inside a star can be used to determine whether it is burning helium. Image: Gabriel Perez Diaz / Instituto de Astrofisica de Canarias

The discovery was puzzling: if Baekdu is burning helium, it should have been much bigger in the past – so big it should have engulfed the planet Halla. How is it possible Halla survived?

As is often the case in scientific research, the first course of action was to rule out the most trivial explanation: that Halla never really existed.

Indeed, some apparent discoveries of planets orbiting red giants using the Doppler wobble technique have later been shown to be illusions created by long-term variations in the behaviour of the star itself.

However, follow-up observations ruled out such a false-positive scenario for Halla. The Doppler signal from Baekdu has remained stable over the last 13 years, and close study of other indicators showed no other possible explanation for the signal. Halla is real – which returns us to the question of how it survived engulfment.

Two stars become one: a possible survival scenario

Having confirmed the existence of the planet, we arrived at two scenarios which could explain the situation we see with Baekdu and Halla.

At least half of all stars in our galaxy did not form in isolation like our Sun, but are part of binary systems. If Baekdu once was a binary star, Halla may have never faced the danger of engulfment.

If the star Baekdu used to be a binary, there are two scenarios which can explain the survival of the planet Halla.

If the star Baekdu used to be a binary, there are two scenarios which can explain the survival of the planet Halla. Graphic: Brooks G. Bays, Jr, SOEST/University of Hawai’i

A merger of these two stars may have prevented the expansion of either star to a size large enough to engulf planet Halla. If one star became a red giant on its own, it would have engulfed Halla – however, if it merged with a companion star it would jump straight to the helium-burning phase without getting big enough to reach the planet.

Alternatively, Halla may be a relatively newborn planet. The violent collision between the two stars may have produced a cloud of gas and dust from which the planet could have formed. In other words, the planet Halla may be a recently born “second generation” planet.

Whichever explanation is correct, the discovery of a close-in planet orbiting a helium-burning red giant star demonstrates that nature finds ways for exoplanets to appear in places where we might least expect them.

This article is republished from The Conversation under a Creative Commons license. Read the original article.

This doesn't mean you would know it was slower if you were there at the time. A second would still feel like a second. But, relative to us, it was five times slower.

Sauce: https://mastodon.social/@chrfrde/110651854767609709

Source: Gizmoto

Isaac Schultz

The Webb Space Telescope has taken an image of the ringed planet Saturn, completing its photo album of our solar system’s gas giants.

Webb Telescope Images the Pillars of Creation

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Webb is a $10 billion space observatory launched in December 2021. The telescope consists of two imagers: the Near-Infrared Camera (NIRCam) and the Mid-Infrared Instrument (MIRI). Webb has been producing scientific images since July 2022.

Though one of Webb’s primary focuses is the earliest light it can see, which dates back to several hundred million years after the Big Bang, it also is providing insights on our stellar neighborhood. The new image of Saturn complete’s the telescope’s tour of our solar system’s gas giants, or the nearby worlds mostly composed of helium and hydrogen.

Jupiter was the first planet to be imaged by Webb, in August 2022. The Webb team produced an image of Neptune—including its rings and moons—in September and followed that image up with a shot of the rings rimming Uranus, the seventh planet from the Sun.

The image of Saturn was taken on June 25, using Webb’s NIRCam. Saturn appears quite dark because the planet’s methane absorbs much of the sunlight that hits the planet’s atmosphere. The planet’s rings, mostly composed of ice and rock, remain luminous.

The Cassini division, a gap between the planet’s A ring and B ring caused by the gravitational pull of Saturn’s moon Mimas, is also visible in the image.

And speaking of moons: on the left side of the image are the Saturnian satellites Dione, Tethys, and Enceladus. Webb imaged Enceladus in May, and found a 6,000-mile-long (9,660 km) water plume spewing from the icy moon. Enceladus is of significant scientific interest because it has a subsurface ocean, and water is a prerequisite for life as we know it.

Last month, data from the Cassini spacecraft—whose mission ended in 2017, when it plummeted into Saturn’s atmosphere—revealed the presence of phosphorus in Enceladus’ water, another boost to the prospect of life hiding away beneath the moon’s icy crust.

But until a dedicated mission to Enceladus gets off the ground, we may have to settle for the insights of Webb’s unflinching gaze.

More: Then and Now: Our Earliest Close-Ups of the Planets Compared to Today’s Best Shots

exoplanets.nasa.gov:https://gizmodo.com/webb gizmodo.neptune-rings gizmodo.uranus gizmodo.com/webb-telescope-spots-large-plume gizmodo.com/saturn-moon-enceladus-phosphorus caps.gsfc.nasa.gov/simson/kingswood/rings/

Too much to link and source. Definitely worth a click through!

https://lemmy.world/pictrs/image/453125ff-c765-447a-a56a-8ab854236082.jpeg