StarDate

When the Moon covers the Sun during a total eclipse, a couple of rare sights greet viewers. One is the corona – the Sun’s hot but thin outer atmosphere, which looks like a silvery halo. The other is the short red or pink tendrils known as prominences – eruptions of gas into the corona. They’re actually there all the time, but they’re impossible to see against the brilliance of the Sun’s disk.

Prominences can span many thousands of miles; the largest are about half the size of the Sun itself. They’re actually thousands of degrees cooler than the surface of the Sun. They look bright only when they’re seen against the dark background of space. When they’re seen against the Sun, they form dark streaks.

Prominences are powered by the Sun’s magnetic field. Strands of the field can levitate above the surface. The strands can be filled with plasma – hot gas that has an electric charge.

Some prominences are common around magnetically active regions. They can erupt in minutes, loop into the corona, then collapse within hours.
Others form in regions that are fairly quiet. They can take days to bloom into the corona, then remain visible for weeks or months.

Some prominences don’t stop at the corona. They can send huge clouds of plasma into the solar system. If they hit Earth, these outbursts can trigger brilliant auroras and disrupt technology – prominent impacts from the Sun.

Script by Damond Benningfield

To predict the lifespan of a star, you don’t need a crystal ball – a bathroom scale will do just fine. Heavier stars age faster, so if you know the star’s mass, you have a good idea of its future.

Consider Tarazed, the second-brightest star of the eagle. It’s only about six percent the age of the Sun. But because it’s about three and a half times the Sun’s mass, it’s already completed the “prime” phase of life. Now, it’s well into the next phase – as a red giant.

Mass is critical because, as the star’s mass increases, so does its gravity. Stronger gravity squeezes the star’s core more tightly, increasing its temperature. That revs up the rate of nuclear reactions in the core.

When a star is born, its core is mostly hydrogen. In the prime phase of life, the star “fuses” the hydrogen atoms to make helium. When the hydrogen is gone, the core shrinks, so it gets even hotter. That causes the star’s outer layers to puff up, which is what’s happened to Tarazed – it’s more than 90 times the Sun’s diameter.

Higher core temperatures trigger the next round of reactions. So today, Tarazed is fusing the helium to make heavier elements. Eventually, that will end as well. Tarazed will shed its outer layers, leaving only its tiny, dead core – ending the star’s fairly short but bright life.

Tarazed is low in the east at nightfall. It’s close above even brighter Altair, at the southern point of the Summer Triangle.

Script by Damond Benningfield

Altair is one of the highlights of summer. It’s at one point of the Summer Triangle, and it’s the twelfth-brightest star in the night sky. And it’s just 16.7 light-years away.

Because Altair is so close and bright, we know quite a bit about it. And we’re learning more all the time. A study a couple of years ago, for example, refined the likely age of the star – 88 million years, give or take 10 million. That’s just two percent the age of the Sun.

Altair is about twice the size and mass of the Sun. And because it’s so young, it spins in a hurry – one turn every eight hours or so, versus 25 days for the Sun. That whirling rotation makes the star look squished – it’s about 25 percent wider through the equator than the poles.

In 2022, astronomers “listened” to the star with a space telescope. It measured vibrations on the surface of the star. Combined with observations from the ground, that revealed a total of 34 vibration modes – like 34 different musical notes.

The vibrations travel deep into the star. Each “note” reveals details about Altair’s interior. Piecing together the whole symphony, the astronomers found that the core of Altair contains more than 97 percent of the hydrogen it was born with. As a star ages, it converts its hydrogen to helium. So the amount of hydrogen reveals that Altair is just starting out.

Script by Damond Benningfield

A wave of starbirth is sweeping through Scorpius and some nearby constellations. It started about 20 million years ago, and is continuing today. It’s triggered the birth of thousands of stars, including some of the most impressive in our part of the galaxy.

The complex is called the Scorpius-Centaurus association. It consists of three distinct regions that appear to be related. Giant clouds of gas and dust in one of those regions began collapsing tens of millions of years ago. That gave birth to the first stars in the association.

The most massive members of that group produced winds and radiation that squeezed the surrounding clouds. And some of those early stars exploded, creating shockwaves that compressed the clouds even more. That triggered the birth of many more stars.

Many stars in the association are extremely big, bright, and massive. They account for many of the bright lights that outline the scorpion, the centaur, and other constellations in the region. For every one of those stars, there are hundreds of less-massive stars.

From Earth, the most impressive member of the association is Antares, the heart of the scorpion, which is quite near the Moon tonight. Antares is more than a dozen times the mass of the Sun, and tens of thousands of times brighter. In the next million years it’s likely to explode as a supernova – perhaps triggering the birth of even more stars in this busy complex.

Script by Damond Benningfield

Two stars that sound a bit scary peek above the southern horizon on summer nights. Together, they form the “stinger” – the end of the curving body of the scorpion.

The stars are Lambda and Upsilon Scorpii. Lambda is the brighter of the two. It’s also the more complicated – it consists of three stars.

The system’s details are a bit uncertain. That’s largely because its distance is uncertain. Estimates range from about 365 light-years to almost twice that range. Without a good measurement of the distance, it’s tough to figure out how big and heavy the stars really are.

We do know that the system consists of a tight binary – two stars that orbit each other once every six days – plus a third star that orbits the others every three years.

One of the stars in the binary is much bigger and brighter than the Sun, and 10 to 14 times the Sun’s mass. That means the star will end its life with a colossal explosion.

Its close companion is maybe twice the mass of the Sun. But it’s not yet fully formed. The distant companion is another big guy – roughly 8 to 10 times the mass of the Sun. If it’s at the high end of that range, then it, too, will explode as a supernova. If not, its fate is less certain. It could become a supernova, but it also might expire in a more gentle process – a fate similar to the Sun’s.

More about the scorpion tomorrow.

Script by Damond Benningfield