Nebulae: Crash Course Astronomy #36

00:03

Astronomers have it pretty easy when we talk to the public. I may be biased, but I think

00:08

astronomy is the most beautiful of all sciences. Sure, other fields of science have lots of

00:13

eye candy, but all I have to do is pull out a shot of Saturn, and I win. Because Saturn.

00:18

It’s ALL gorgeous. Planets, moons, stars, clusters…but of all of them, you just can’t

00:22

beat a nebula. Why?

00:24

Because nebulae.

00:36

“Nebula” is Latin for “cloud” and for once in astronomy we have a name that

00:40

actually describes the object accurately. Nebulae are clouds of gas and dust in space.

00:45

I’ve already talked about them a bit. For example, stars form from nebulae; our Sun

00:49

did 4.6 billion years or so ago. When a medium-sized star dies, it blows off winds of gas, then

00:56

lights them up as the white dwarf core of the star is revealed, creating a planetary

01:00

nebula. Also, when a high-mass star explodes it catastrophically vaporizes itself, becoming

01:06

a violently expanding cloud of gas. Nebulae are literally part of the births, lives, and

01:11

deaths of stars.

01:13

So, besides being beautiful, they’re also pretty versatile.

01:15

There are a lot of ways of categorizing nebulae. One way is by how we see them. For example,

01:21

if a cloud of gas is blasted by light from a nearby massive star, the gas in it becomes

01:25

excited; the electrons in its atoms jump to a higher energy level. When the electrons

01:30

drop back down, they emit light. The gas glows, and we call this an emission nebula.

01:35

The color of an emission nebula depends on the gas in it and how hot it is. Hydrogen,

01:39

for example, glows most strongly in the red, and we see that color in most emission nebulae.

01:44

Oxygen tends to glow green, but to a lesser extent it gives off blue light too.

01:48

Other elements span the spectrum in colors they give off.

01:51

And these colors aren’t limited to visible light. Hydrogen can emit infrared and even

01:55

radio light, and if it’s energized enough it’ll emit in the ultraviolet, too. That’s

02:00

true for many elements.

02:01

Although most emission nebulae look substantial, they’re actually incredibly tenuous. A typical

02:07

density in a gas nebula is only a few thousand atoms per cubic centimeter. Mind you, in the

02:12

air you breathe there are about 10^19 atoms per cubic centimeter, a thousand trillion

02:17

times denser than a typical nebula! Really, a nebula is barely more than a vacuum.

02:21

The reason they look so cloudy is that they’re big. Really, really big. A decent sized nebula is

02:28

several light years in diameter, and that’s a LOT of centimeters. That much gas adds up,

02:34

and so some nebulae can be pretty bright.

02:36

While EMISSION nebulae glow due to their own light, REFLECTION nebulae are bright because

02:40

— can you guess? — they reflect the light of nearby bright massive stars. In this case

02:46

though the nebula isn’t made of gas, but is instead mostly dust.

02:50

I don’t mean like the hair and skin flake dust bunnies you find under your couch either.

02:54

When astronomers talk about dust, they mean tiny grains a micron across. Just so you know,

03:00

a human hair is 100 times wider than that! These tiny grains contain things like things

03:05

like silicates, aluminum oxide, and calcium. And in many cases this dust is laced with

03:10

complex molecules called polycyclic aromatic hydrocarbons.

03:13

While I love that fancy name for them, you might know them better as… soot. Yup. When

03:18

you light a match you’re pretty much making some of the same stuff that lurks between the stars.

03:23

Dust doesn’t emit visible light. But it can affect the visible light from stars if

03:28

they’re inside the dust cloud or nearby. Turns out,

03:31

dust is very good at scattering light. That means that when light hits it, the light gets

03:36

sent off in some other direction. This scattering is highly wavelength dependent, so blue light

03:41

is scattered very strongly, while red light can go right through.

03:44

We saw this in the last episode; the dust surrounding the Pleiades star cluster is a

03:48

reflection nebula. The light from the stars in the Pleiades is scattered by the nearby

03:52

dust, and the blue light light gets sent in every direction, including toward us. The

03:57

red light doesn’t scatter nearly as well, so we don’t see it; it never gets sent toward us.

04:02

Thick dust is also very good at absorbing visible light. If a star is embedded in enough

04:07

dust, the light from it is dimmed considerably. If the cloud is dense enough or big enough

04:12

the dust can completely extinguish the light seen from a star.

04:15

At the same time, if the dust is at the right density, the blue light from a star inside

04:19

a dust cloud gets scattered, while the red light can get through. This effect reddens

04:24

starlight, and in some dust clouds it provides a striking view: Stars outside the cloud look

04:29

normal enough, but closer in they get redder and redder, and then fade out entirely. The

04:33

result is a fuzzy, red-edged hole in space. Pretty cool.

04:37

You can see that effect in Barnard 68, a small dust cloud, just half a light year in size.

04:42

These are also sometimes called molecular clouds; they’re cold enough that atoms can

04:46

stick together to form molecules. Their cores can be hundreds of degrees below 0 Celsius.

04:51

Some dust clouds like this are relatively small, but others get downright huge. We call

04:57

these giant molecular clouds, because why not. These can be incredibly massive, with

05:01

thousands or hundreds of thousands of times the mass of the Sun, and stretch for hundreds

05:06

of light years.

05:07

And that brings us to one of the most glorious objects in the sky: the Orion Nebula. This

05:12

is an emission nebula located just below Orion’s belt. It’s actually a naked-eye object,

05:17

visible in modestly dark skies. It looks like a star by eye, but even binoculars reveal

05:22

it to be fuzzy, and through a telescope, or with long exposure images, you get unmitigated majesty.

05:29

The Orion Nebula is a star-forming factory; a bunch of stars have been born in it. Some

05:33

of them are very massive and incredibly luminous. The entire nebula is lit by four stars located

05:39

in its heart, collectively called the Trapezium. These are four brutes; huge, brilliant stars

05:45

that are each far more massive than the Sun. Their light is so fierce it illuminates the

05:50

entire nebula, which is about 20 light years across.

05:53

And here’s a funny thing about Orion: What you’re seeing is not just a gas cloud in

05:58

space. It’s actually just a bubble sitting on the edge of a much, MUCH larger molecular

06:03

cloud, hundreds of light years across. That cloud is cold and dark, and so we don't see

06:08

it by eye. The Trapezium stars formed inside that cloud, very near the edge. When they

06:13

turned on, fusing hydrogen into helium, they started blasting out a mind-numbing amount

06:18

of ultraviolet light, which began eating away at the gas and dust. Eventually, they blew

06:23

a hole in the side of the cloud, like a weak spot in a bicycle tire blowing out.

06:27

What we see as the magnificent Orion Nebula is just a dimple, a cavity, in the side of

06:32

the cloud, filled with gas heated to glowing by the stars.

06:36

There are still stars forming there today, too. I mean literally, right now. We can see it happening!

06:41

In Episode 9, I talked about the solar system, and how it starts off as a flattened disk

06:46

of gas and dust. When we look at the Orion Nebula with Hubble, WE SEE THOSE DISKS. They’re

06:51

called protoplanetary disks and they’re so dense they absorb almost all the light

06:56

from the stars forming inside them, so they’re dark, and we see them in silhouette against

07:00

the brighter gas of the nebula.

07:02

Unless you look in the infrared. That kind of light can pierce the dark disk, and when

07:06

we use infrared telescopes we can see the protostars forming in the centers of those

07:12

disks. Take a good look: THOSE ARE BABY STARS, literally stars that are forming right this

07:17

very minute. They’re still hot due to their contraction, but in a few million years they’ll

07:21

ignite fusion in their cores, and become real stars. They’ll blow away the remaining material

07:26

around them, revealing themselves, and perhaps any planets orbiting them as well.

07:31

In fact, once stars start forming inside a nebula, its days are numbered. The Eagle Nebula

07:36

is another star factory, with active star birth going on inside of it. Some of these

07:40

are massive, luminous stars, and give off so much ultraviolet light it erodes away at

07:44

the surrounding nebula, in a process called photoevaporation. However, dense knots of

07:49

material forming new stars can resist that erosion better, and protect the material behind

07:55

them, in essence shadowing it. This results in long fingers of material we

07:58

see in silhouette against the hotter gas, like sandbars in a stream. Observing their

08:03

infrared light, we can also see the stars embedded inside them.

08:07

There are several of these giant towers in the Eagle Nebula, three of which have been

08:10

called the Pillars of Creation. Stars are forming at their tips. Eventually, though,

08:15

the light from the massive stars will win, zapping away at the structures, dissolving

08:19

them. There’s also some very hot gas in the nebula that might be the result of a star

08:23

that has already exploded; if so, then the pillars REALLY don’t have long to live.

08:28

In a few thousands years they won’t be eroded away, they’ll be BLASTED away.

08:32

In a lot of nebulae there’s no sharp edge; they just kinda fade away. Sometimes that’s

08:37

because the gas thins out, so there’s not enough stuff there to get lit and see. Other

08:41

times it’s because there’s just one or maybe a few stars lighting up the whole cloud,

08:46

and at some distance from them the starlight fades and can’t illuminate the gas anymore.

08:50

But sometimes nebulae do have sharp edges. That usually happens when a gas cloud is expanding,

08:56

like in a planetary nebula or supernova. The gas slams into the much thinner gas that is

09:00

strewn between the stars, what we call the interstellar medium. The expanding gas piles

09:05

up like snow in a snowplow, getting denser and glowing more brightly.

09:09

Gas inside a nebula can be in turmoil, too. Winds from stars compress the gas, shock waves

09:14

form when stars explode and when they’re born. These can create lovely sheets, tendrils,

09:19

and filaments in nebulae as well.

09:21

All of these factors can come together to create great beauty. Not too far from the

09:25

Orion Nebula in the sky is another dark nebula, superposed on a bright emission nebula. By

09:31

coincidence, the dense dark material is shaped like a gigantic chess piece, and it’s called

09:36

the Horsehead Nebula. It’s being eroded by a star called Sigma Orionis, off the top

09:40

of the frame here, and that’s also making the gas behind it glow in that sharp ridge.

09:45

One of my favorite nebulae in the sky is Barnard’s Loop, a huge arc of material that’s formed

09:50

either by the expanding gas from supernovae or the winds of all the massive stars being

09:54

born in the Orion complex. It’s also the outer edge of a huge bubble surrounding a

09:59

substantial amount of real estate in the constellation Orion. In this image you can see both the

10:04

Orion and the Horsehead nebulae; the Loop is so big you could fit 25 full Moons across it!

10:10

One more thing: I’ve been talking about bright and dark nebulae, but that’s an old

10:14

fashioned way of thinking of them. I’ve also mentioned that infrared light can get

10:18

through them, but remember from Episode 24 that the kind of light an object gives off

10:22

depends on its temperature. Clouds of dust that look dark to the human eye are actually

10:26

glowing if you observe them in the far infrared, well outside the colors our eyes can detect.

10:32

But we have telescopes that can see at these much longer wavelengths.

10:36

In Orion, there’s a reflection nebula called M 78. Between M78 and Earth are long filaments

10:42

of very cold and dark dust, blocking the light from the reflection nebula behind and looking

10:47

like dark rivers running through it. But when you use a telescope that can see light with

10:51

a wavelength of a millimeter or so, that dust glows brightly, threading through M78 like ribbons of fire.

10:57

Like so much else in life, what you see really depends on how you see it. If there’s a

11:02

life lesson there, feel free to take it.

11:04

Today you learned that nebulae are clouds of gas and dust in space. They can glow on

11:08

their own or reflect light from nearby stars. When they glow it’s usually predominantly

11:13

red from hydrogen and green from oxygen, and when they reflect and scatter light it’s

11:18

from massive hot stars, so they look blue. Stars are born in some nebulae, and create

11:22

new ones as they die. Some nebulae are small and dense, others can be dozens or hundreds

11:27

of light years across.

11:28

Also? They’re incredibly beautiful.

11:31

Crash Course Astronomy is produced in association with PBS Digital Studios. Head over to their

11:35

YouTube channel to catch even more awesome videos. This episode was written by me, Phil

11:40

Plait. The script was edited by Blake de Pastino, and our consultant is Dr. Michelle Thaller.

11:45

It was directed by Nicholas Jenkins, edited by Nicole Sweeney, the sound designer is Michael

11:49

Aranda, and the graphics team is Thought Café.