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  • When you hear the wordsblue supergiant’, you’d be forgiven for thinking of a fairy

  • tale creature.

  • But the reality is actually far more fantastical: elusive astrophysical bodies that are notoriously

  • difficult to see and understand but which hold the keys to the formation of stars and

  • galaxies.

  • And for the first time, we can now see what’s inside them.

  • In the classification of stars, temperature is what determines color.

  • Just like the hottest part of a flame is that blue part at the bottom, the hottest stars

  • in the universe are blue.

  • And blue supergiant starsas their name would suggestare huge, with masses anywhere

  • upwards of 10 times that of our Sun.

  • Theyre also much brighter and much hotter than mid-size stars like the Sun, making them

  • some of the most visible and recognizable stars in the night sky even though theyre

  • actually quite rare.

  • They burn hot and fast, only lasting, oh around tens to hundreds of millions of years or so.

  • And that’s compared to our Sun’s expected lifetime of 10 billion years.

  • Because they flame out so fast, relatively speaking, that makes them difficult to study.

  • With the advent of advanced telescopes both on the ground and in space, weve been able

  • to observe their surfaces, but we still know relatively little about what goes on inside

  • them.

  • Something has to be happening to produce their incredibly intense luminositytheir brightnesswhich

  • seems to shimmer and twinkle.

  • And new research has produced some of the first models of the interior of these enigmatic

  • stars, telling us a little more about how all this showstopping behavior comes to be.

  • A cooperative research effort between Newcastle University in England and KU Leuven in Belgium

  • used existing photometric data gathered by NASA’s Kepler/K2 satellite and the Transiting

  • Exoplanet Survey Satellite or TESS.

  • These satellitesoriginal purpose was to scour the galaxy for exoplanets, or planets

  • beyond our solar system.

  • But to do that, they surveyed hundreds of thousands of the brightest stars near our

  • sun, building a super handy data set for scientists interested in looking at bright stars...data

  • that confirms their existing hypothesesand simulationsof how these stars behave.

  • Because the satellites, with their very sensitive detectors, were looking out at the sky for

  • a long enough period of time, they let us see what weve never seen before: the patterns

  • of shimmering and twinkling on blue supergiants.

  • Or, to put it in a morescientificway, the coherent pulsations...indicating that

  • the stars are being rippled by internal gravity waves.

  • These are not to be confused with gravitational waves.

  • Gravity waves are disturbances in some substance due to the restoring effect of gravity: Say

  • a substance was going in one direction because of some other force like wind traveling across

  • the ocean, but the water is also being forced down by gravity, whichin combination with

  • the water’s natural buoyancy and other physical factorsresults in disturbances of the water

  • that we know as waves.

  • This happens in our oceans and our atmosphere all the timebut it’s a very different

  • phenomenon from gravitational waves, which are tiny perturbations in the fabric of spacetime

  • due to some huge cosmic collision.

  • Different things, confusingly similar name, and though theyre common in our own oceans,

  • gravity waves are also what’s happening inside blue supergiant stars!

  • In analyzing their data set, the research team observed the presence of an entire spectrum

  • of low-frequency gravity waves in blue supergiants.

  • These flow through the star and break at the surface, a lot like ocean waves breaking onto

  • a beach.

  • These frequencies also include standing waves, a type of wave that’s a lot like a seismic

  • wave from an earthquake.

  • This revelation means that we can now delve into blue supergiants using asteroseismology.

  • Studying these frequencies allows astrophysicists to work out the chemistry and physics that’s

  • likely going on inside these stars, including at their core.

  • These calculations can tell us how metal is being produced in the stars and how it moves

  • around inside them... which is very important because blue supergiants are like the metal

  • factories of the universe, producing most of the chemical elements on the periodic table

  • past helium.

  • But perhaps even more importantly, this new information gives us insight weve never

  • had before into how the lives of these stars might end.

  • When these incredibly energetic and short-lived stars die, they explode into supernovae and

  • form a black hole or a neutron star.

  • What’s ejected in that explosion and what’s left over afterwards has a significant impact

  • on the formation of other stars and on the evolution of the galaxy around it.

  • As the researchers put it, massive stars like blue supergiants, “determine the evolution

  • of the cosmos.”

  • The results of this research gives us new ways to look at these potential supernovae,

  • like using asteroseismology, to produce highly accurate models of their ages, what’s going

  • on in their core, their rotation, angular momentum transport, interior mixingall

  • of which could tell us more about when and how theyll die, and what theyll put

  • out into the universe when they dowhich could potentially inform our understanding

  • of how other galaxies and stars formed before them, too.

  • If you want even more galactic exploration, check out my other video here about the universe’s

  • first molecule.

  • Make sure to subscribe to Seeker for more explorations of the universe, and as always,

  • thanks for watching.

When you hear the wordsblue supergiant’, you’d be forgiven for thinking of a fairy

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