The Universe s02e16 Episode Script
Biggest Things in Space
ln the beginning, there was darkness and then, bang giving birth to an endless, expanding existence of time, space, and matter.
Now, see further than we've ever imagined beyond the limits of our existence in a place we call "The Universe.
" The biggest things in space are gargantuan beasts.
Each one is a heavyweight in its galactic division.
The universe is an unimaginably large place.
lt's so big it's really hard for human beings to actually comprehend things ofthese size scales.
On Earth and in the universe, size matters but it matters in different ways.
ln space, bigger is not necessarily better.
And oftentimes, the winners live large and die young.
They're the Mount Everests ofthe cosmos.
Astronomers aim their telescopes at them like paparazzi eager to capture images of their every movement.
They are the biggest things in the universe and their sizes are truly mind-boggling.
The good thing about being huge in the universe is that the universe is even huger than you are so there's plenty of space to stretch out and get your size measured among intelligent civilizations that are having a look.
The first thing you find out when you start studying astronomy is how darn big everything is.
Almost everything you're studying is so far beyond any kind of human scale that we're ever going to encounter in our normal lives.
The universe is brimming with gigantic objects.
Within our own solar system Earth is the fifth biggest planet but it's a hundred million billion times smaller than the largest stuff in space.
So what holds the coveted title as the biggest thing in the universe? Most astronomers agree it's the cosmic web an endless scaffolding of superclusters of galaxies surrounded by dark matter an invisible and mysterious form of matter that accounts for 90 percent ofthe universe's mass.
The largest thing in the universe you might even wonder if it's a thing at all it's a web of dark matter that fills the volume ofthe universe.
Dark matter is this matter that we can't even see.
lt doesn't emit any light but it is filled throughout the universe and there's structure in it.
Dark matter is something much more mysterious than most people know.
Literally, the stuff that makes me up dark matter isn't made of that.
l don't think you could smell it l don't think you could touch it.
lt simply has gravitational attraction.
The cosmic web of dark matter becomes visible when looking at the objects that fill it.
This cosmic web really is almost like a three-dimensional spider"s web.
At the very center of all the vortexes there are the superclusters clusters of thousands of galaxies and then filaments of galaxies connect them all the way across the volume of the universe.
The deepest, strongest gravity at the intersections of these weblike structures is where all the gas falls and that's where galaxies form-- clusters of galaxies form.
Butjust how big is the cosmic web? lf the Milky Way galaxy were the size of a poppy seed then the observable universe, everything we can see would be about the volume of the Rose Bowl stadium.
Now, that entire volume is filled with a cosmic web superclusters linked together from one side of the universe to the other.
The origins of the cosmic web remain uncertain but scientists think its initial seeds were planted in the Big Bang, the beginning of the universe.
During the Big Bang explosion the whole universe blew up, essentially and expanded very rapidly so the cosmic matterweb contains all of the original matter that was created during the Big Bang just blown up into the very, very large structures that we see today.
Scientists are actively trying to map out the cosmic web which spans the entire universe.
One way is to look at hot, x-ray-emitting gas and how it's contained by the gravity present in the dark matter.
Anotherway is to look at something called gravitational lensing, where light is bent by the gravity of the cosmic web and so we're able to sort of see the outlines of that cosmic web by the way it distorts the light that's behind it.
The cosmic web basically contains everything in the universe but some scientists question whether it's technically the largest object because the web isn't continuously connected throughout space.
The cosmic matterweb is not actually the largest gravitationally bound object in the universe because all the matter in the universe has expanded so vastly the force of gravity is not enough to keep it together in one area whereas superclusters of galaxies are actually gravitationally bound meaning that they have enough mass to produce enough gravity to hold them together over the passage of time.
Astronomers don't have a firm estimate but the cosmic web could be made up of hundreds ofthousands of superclustered complexes.
These are mega collections of galaxies gravitationally bound up to hundreds of millions of light-years across.
The universe is organized hierarchically.
Stars make up galaxies galaxies make up clusters clusters make up superclusters.
You could draw an analogy that a cluster might be the North American continent and a supercluster might be the association of cities on the North American continent cities on the European continent cities on the Asian continent, et cetera.
The current record holder for the largest supercluster of galaxies is called the Shapley Supercluster.
This dense region of galaxies is 400 million light-years long.
So it would take the fastest interplanetary spacecraft trillions ofyears to travel across it.
The Shapley Supercluster spans several constellations and is almost from our Milky Way galaxy.
l have here a small toy boat which is a replica of the Queen Mary which you can see here behind me.
And this little toy is about 4,000 times smaller than the real Queen Mary.
lfyou could just imagine that our own Milky Way galaxy that we live in is the same size as this toy boat then one of the most massive superclusters that we know about, the Shapley Supercluster would be the same size as theQueen Mary.
So the Shapley Supercluster would be about 4,000 times larger than our own Milky Way.
lt's one of the most massive things we know about in the entire universe.
Astronomers have known about superclusters since the 1950s but now they've determined their origin through recent measurements ofthe cosmic microwave background which is actual radiation left overfrom the Big Bang.
lt's been concluded that all superclusters including the Shapley Supercluster originated during the formation of the universe over13 billion years ago.
As the universe evolves and expands gravity is an attractive force so any region that has a little extra density there attracts more matter and more matter.
So, Shapley is a cluster that basically had the accumulation of many other little galaxies falling into it and that's how it's gotten so big over time.
lncredibly, scientists think the Shapley Supercluster may be even bigger than it appears.
ln fact, we may only be seeing a small fraction ofwhat's really contained within the Shapley Supercluster.
When the Wide-Field lnfrared Survey explorer launches we should be able to see about10 times farther away and hopefully, we'll be able to see the rest of the Shapley Supercluster to see if it is even more massive than what we already know about.
Superclusters of galaxies will stay together over time because they're gravitationally bound.
Gravity is holding them together.
So, even though the universe is expanding over time those superclusters of galaxies will stay together and they'll always keep orbiting each other.
We humans also live in a supercluster complex but it's less than half the size and about10 times less massive than the Shapley Supercluster.
Our Milky Way is part of a small, little cluster called the Local Group which is part of a larger cluster called the Virgo Cluster sort of on the outskirts ofthat.
So it's like your home address.
You live on this street, in this town in this state, in this country.
Similarly, the Milky Way has its larger and larger associations ofwhich it's a part.
Superclusters of galaxies are the most crowded neighborhoods in space but they surround equally big regions where almost nothing exists.
These bare spots are called voids.
Voids are the opposite of clusters.
lf clusters are where all the galaxies are voids are where all the galaxies aren't.
And you do see this kind offrothy, weblike structure of clusters and voids and clusters and voids.
So it's kind of like cities and countrysides cities and countryside.
The largest confirmed void in the universe remains Bootes.
Named after the constellation where it resides this near-empty space is a whopping 250 million light-years across.
That's equal to 2,500 Milky Way galaxies placed side by side.
Look out into the cosmos in any direction and you'll see something.
You'll see stuff, you'll see galaxies you'll see gas, dust, you'll detect dark matter.
Everywhere you look, there's something.
Yet here's this giant hole with nothing in it.
The Bootes Void, which was discovered in 1981 is almost completely devoid of galaxies.
A newway to search for even largervoids may be possible by precise measurements of the temperatures of the cosmic microwave background radiation.
Subtle cold spots in this radiation could locate the directions of large distant voids.
The story of theirformation is basically the reverse of how superclusters form.
The voids must have started out in the first microsecond ofthe Big Bang as slightly low-density regions.
But with time, they became less and less dense.
All ofthe matter flowed away into the sheets and filaments leaving the voids emptier and emptier of matter until today, there is almost nothing but a few little dwarf galaxies in some of these voids.
Voids and superclusters are just some ofthe big things contained in the even larger structure called the cosmic web.
But the web also holds other immense objects including colossal bubbles that might hold missing clues to the formation of galaxies.
The universe is packed with monstrous things.
Researchers have recently discovered giant clouds of gas that resemble something out of a horror movie.
These mysterious objects are called Lyman-Alpha blobs.
My personal favorite biggest objects in the universe are the Lyman-Alpha blobs an unpredicted, unexpected phenomenon where you're catching a galaxy in the first phases of its formation and collapse.
A Lyman-Alpha blob is very much like this expanding soap bubble except, in the case of the soap bubble it's the airwhich is making it fill up.
A Lyman-Alpha blob is expanding because of heat.
A lot of energy has been injected into this gas to make it heat up.
And when you put all that energy into a gas it inevitably tends to puff up and expand exactly like an expanding bubble.
ln the case of a Lyman-Alpha blob, it's being puffed up by heat and maybe also by the ultraviolet radiation from newly formed stars.
The largest known Lyman-Alpha blob is a colossal, amoeba-shaped structure that resembles a giant greenjellyfish.
lt's 200 million light-years wide and is located in the constellation Aquarius.
When we're looking at the Lyman-Alpha blob we're seeing gas that sort of spread amongst these very first stars and galaxies.
lt's kind of an amorphous shape of about 30 separate little blobs inside of it.
lt's very large and very massive.
The whole structure is about of our own Milky Way galaxy.
The Keck and Subaru telescopes in Hawaii contain special filters that are able to see this faraway blob which spreads out along curvy tentacles.
Scientists estimate that the largest Lyman-Alpha blob was formed about almost two billion years after the Big Bang.
The observational technique we use to see that gas refers to a very specific color of light, emission of light that's called Lyman-Alpha.
So you hear a phrase Lyman-Alpha blob because ifyou take an image of the sky through a filter that gives you only that Lyman-Alpha light that very special wavelength of light you'll see a little blob on the sky.
Lyman-Alpha blobs are perhaps precursors to the galaxy clusters we see today.
Within these gigantic bubbles may exist cocoons that will one day spawn new galaxies.
The Lyman-Alpha blobs are probably a fairly special short-lived phase in the evolution to creating a galaxy.
l would expect that most of them are going to collapse and form young galaxies in the next100 million years or so of their lives so it's a special phase just when a galaxy is beginning to pull itself together.
The search in the universe for Lyman-Alpha blobs isjust beginning.
We'll undoubtedly find many more ofthem and even perhaps some larger ones in the future.
Stay tuned.
Lyman-Alpha blobs may hold the answers to the formation of individual galaxies which are gravitationally bound systems containing stars, gas, dust, and dark matter.
At least100 billion single galaxies exist in the observable universe.
They range in size from ten thousand to millions of light-years across.
Galaxies, these titanic collections of stars l think of them as cities having been born in one myself not only a galaxy, but also an actual city a native of New Yorkwhere everyone is crowded together.
Galaxies are sort of how matter has organized itself in the universe.
ln the competition for largest single galaxy in the universe sizing up a winner is challenging.
The problem in saying what's the largest galaxy is in deciding where they end.
Galaxy does not have a sharp edge.
ltjust gets thinner and thinner as you go further out.
lt's exactly analogous to saying where is the end of a very large metropolitan area? Where is the end of Los Angeles? You can go out 50 miles and you'll still find a fairly high density of suburbs.
The suburbs of a big galaxy like the Milky Way extend out very, very far, more than 100,000 light-years.
And with a giant galaxy, those suburbs extend out hundreds of thousands of light-years.
Since scientists can't determine a clearwinner several galaxies share the title as biggest.
They're called cluster-diffused or CD galaxies and they sit in the centers of rich clusters of galaxies.
lfyou think about the cosmic web as being sort of like a three-dimensional spiderweb well, then, the spiders lurking in the middle ofthe web are these monstrous CD galaxies, as we call them.
These galaxies can have masses that are in some cases maybe 10 times or 20 times the mass of our own Milky Way.
These CD galaxies are the largest galaxies in the universe.
For example, lC-1101 sits in the center of a galaxy cluster called Abell-2029 and it's six million light-years across.
Compare that to our own Milky Way that's100,000 light-years across.
lt's a really big galaxy.
lt's 60 times the size of our Milky Way.
CD galaxies are elliptically shaped as opposed to a disc structure like our Milky Way.
This is because they've achieved their size by bulking up on other galaxies through galaxy mergers.
You may have heard the phrase "galaxy cannibalism" where one galaxy eats another.
That goes on all the time in clusters of galaxies.
And so, sitting usually down at the very center of a massive cluster, you'll find one big galaxy.
These CD galaxies have so much mass that they are the 800-pound gorilla wherever they are.
You see little galaxies maybe orbiting around them but, basically, it's eaten up everything nearby.
The largest galaxies may be six to 20 million light-years across.
However, there are other objects even larger.
They're called radio lobes.
Stretching out from both sides of the galaxy these immense structures are actually hurling jets of charged particles that emit radio waves.
So we're here in this auto body shop where l'm gonna use these two torches to simulate radiojets coming out of opposite sides of an accretion disc swirling around a supermassive black hole.
So in the visible you see a small blue flame coming off ofthe torch.
But in the infrared you can see that the heat from the torch extends much, much further out.
Similarly with the radiojets what you see in the optical is actually quite different from what you see in radio waves.
A typical lobe might be as the lobe spreads out on both sides of the galaxy.
That's about twice the size of the Milky Way galaxy's disc.
Astronomers think radio lobes are powered by supermassive black holes located in quasars.
These are the luminous centers of most active galaxies.
Thejets of radio energy that come from a giant black hole and make these enormous radio lobe structures are very closely related to quasars.
ln fact, in some cases, you can see a low-power quasar in the center of the galaxy and then it's surrounded by these giant lobes to either side.
They have been blasted out by very high-energy jets of electrons that are basically moving at almost the speed of light.
And they are blasted out, probably from the north and south poles of the spinning black hole.
The radio lobes depend on matter going down the black hole.
As matter goes down the black hole some of it gets accelerated up into these lobes.
So the size of the lobes has something to do with the history of how much matter the black hole has actually fed on.
And so over time, they'll change size.
Radio telescopes have surveyed the universe and determined the largest known radio lobe.
The undeniable record holder is located in the galaxy named 3C236 which is in the constellation Leo Minor.
ltsjets span 40 million light-years across.
Scientists don't understand why some active galaxies form thesejets and others don't, but one thing is certain radio lobes will not last forever perhaps for only a few million years.
So, just as this torch will eventually run out of gas and shut itself off thejets from a radio galaxy will eventually die as well.
When the black hole has consumed all of the material in its immediate vicinity there'll be nothing left of the accretion disc to get shot out along the magnetic field lines and thejet will die.
lf black holes are the producers of these gigantic radio lobes then what is the largest black hole in the universe? Scientists are currently placing bets on the winner.
When it comes to the biggest things in the universe some black holes earn a place in the record books.
A black hole is a region of space where the pull of gravity is so immense that nothing can escape it, not even light.
There are billions upon billions ofthese black monsters prowling the universe.
They come in two size categories.
Most ofthem are the stellar mass black holes which are about five to 100 times the mass of our sun.
And then there are supermassive black holes that are millions to billions of times the mass of the sun.
We have the supermassive black holes the kind that we seem to be finding in the centers of every galaxy where we've had the resources to look.
Havoc is wrought upon your environment ifyou're a star orbiting close to one ofthese supermassive black holes in the centers of these galaxies.
Black holes are not physically large regions but when measuring their mass they become top competitors in the galactic heavyweight division.
The center of our Milky Way we know that there's a black hole that's about maybe three million times the mass of our own sun.
And yet, because black holes are so incredibly dense the actual size of the black hole is still fairly small but incredibly, incredibly powerful gravitationally.
As their name suggests, these black beasts are essentially black because no light can escape them.
So one can only be observed when its gravity affects something else in space such as a passing star orwhen it's gorging on matter around it.
So what is the reigning black hole champion? The current record holder for the largest black hole appears to be in the incredibly luminous quasar which has the prosaic-sounding name HS1946+7658.
Why do l say it's the largest black hole? Because we know it is the most luminous quasar in the universe that's been found so far.
The black hole that's holding it together that's producing the energy needs to be about10 billion times the mass of the sun.
That corresponds to a black hole which is larger than our entire solar system.
ln fact, it'sjust out there to remind us how bizarre a seemingly simple force like gravity can actually be.
The largest supermassive black hole wields power in the center of a galaxy but there are other big luminous objects in the universe.
ln fact, there are some that seem to exist everywhere we look.
When we glance into the nighttime sky we see stars, twinkling dots of light that are actually luminous balls of plasma.
Although they may seem small from Earth stars come in a variety of sizes from red dwarfs which are about1/12 the mass of our sun to blue-white super giants that can get as big as 150 solar masses.
Our Milky Way holds 100 billion stars including our sun which is over 300,000 times the mass of planet Earth.
And this cosmic beacon is a literal powerhouse in our solar system.
This natural gas power plant produces about You know, that's enough to power a few hundred thousand homes.
But that's only a tiny fraction of our sun's energy output.
The sun's power is about two billion, billion times the amount of this plant.
So even in spite of its distance the sun is able to warm our entire planet.
Even so, our sun isn't the largest or the most powerful star by a long shot.
The most powerful stars are about a million times as powerful as the sun.
So ifyou wanted to compare that with the Hoover Dam you would need Hoover Dams per person on the planet to generate that much power.
There's really no human scale to imagine this power output.
The largest and most powerful stars that produce this kind of energy are called red hyper giants.
That's a class of stars that's even larger than super giant stars.
So typically, stars like our sun are fusing hydrogen into helium to make their energy.
But hyper giant stars have already exhausted all the hydrogen in their core and they're fusing hydrogen into helium in the outskirts around the core and that makes them extremely hot and energetic and all that energy causes the star to swell up and so the star ends up with a very large surface area surface areas of the size ofthe Earth's orbit or even bigger.
Within the hefty field of red hyper giants VY Canis Majoris appears to have the largest diameter.
lt's 2,000 times wider than our sun and consequently, it would take the world's fastest race car to circle it once.
This stellar champ lives about in the constellation Canis Majoris.
lfyou replace the sun with VY Canis Majoris ifyou put this hyper giant star where the sun is its radius would extend out past Saturn's orbit.
lt would be about nine times as farfrom the sun as the Earth is so this is a much broader in diameter star than our sun is.
Astronomers determine the radius of such a large star by looking at its temperature.
We use measurements ofthe temperature of the star's surface which we can get from the color of the star and then we will also measure the total power output or luminosity of the star.
And by combining those, we can determine what its total surface area is of the star and from that, we get its diameter.
Now, that assumes that you can measure its luminosity fairly well and that you know something about its temperature from its color.
Most of the time theyjust simply appear as pinpoints of light and it's impossible to actually resolve it.
Although there are new instruments now called interferometers which are capable of resolving even very tiny point sources, like stars.
And in some cases there have been direct measurements of stellar diameters.
VY Canis Majoris will not be a title holderforever.
The red hyper giant is losing mass at the rate of almost 30 Earth masses or more peryear.
The largest stars in the universe like VY Canis Majoris are actually dying stars that as stars begin to die they burn their nuclearfuel much less stably.
They puff out over time.
VY Canis Majoris is probably only a few million years old.
Stars that are as massive as it is don't live very long.
They use theirfuel up at prodigious rates then they swell up into this hyper giant state and only live there for a few hundred thousand years a very short time scale and then they will explode.
VY Canis Majoris might have the largest diameter but when it comes to possessing the most mass there's another star that tips the scale.
ln the wide world of stars there are many contenders vying for the title as the largest in the universe.
But when it comes to stars big can mean two different things.
When you talk about the biggest star you can mean one of two things.
You can either mean the star that has the largest diameter oryou might mean what its mass is.
The mass is a measure of how much stuffyou have.
lt's sort of like yourweight when you step on a scale how much matteryour body is made of.
According to some astronomers the most massive star is located in our Milky Way galaxy.
lts part of a binary star system known as A1 which is actually two stars that orbit each other once every four days.
We find there that one of the stars appears to have a mass of about115 times the mass of the sun and the other star is also enormous about 84 times the mass of the sun.
So both stars in this binary are among the most massive stars that we have ever measured.
There may be more massive stars than the combination in A1 in this star cluster but that's the most massive that we've been able to measure directly.
These massive stars will live full, but short lives.
Massive stars are hugely luminous.
Sometimes they can outshine millions of stars in their neighborhood but at a cost.
The cost is they will run out offuel faster than everybody else and when they die, they die spectacularly.
They explode their guts and scatter it across the galaxy.
So the cost of living a high-mass life a high-luminous life the cost of living in the fast lane is that you explode at the end ofyour life.
A bright star may burn out faster and die sooner but at the same time those hot stars are cooking up elements that are essential for life.
So without really massive stars, we wouldn't be here because you wouldn't get the iron in my blood and the calcium in my bones.
All ofthose things are formed only in the most massive stars.
We humans need essential elements from massive stars but we also need a planet with a firm surface to stand on.
Planets come in two size groups large gas giants like Jupiter and small rocky terrestrials such as Earth.
ln our own solar system Jupiter is the largest planet while Earth trails in fifth place.
Yet, even though Jupiter reigns supreme in our galactic zip code it's not the biggest planet in the universe.
The largest planet with a well-known radius is called TRES4.
lt's named after the Trans-Atlantic Exoplanet Survey that discovered it in the constellation Hercules in 2006.
TRES4 is unusually large for its mass.
We can actually directly measure its radius and this particular planet has an unusually large radius.
lt's about 70 percent bigger than Jupiter yet it has only about 80 percent of Jupiter"s mass.
That's about the same density as cork or even whipped cream.
lfyou look at Earth it's a rocky planet, very dense and then even the gas giant planets like Jupiter are compressed gas and water and other chemicals very tightly compressed.
This thing, TRES4, is like a marshmallow.
Although TRES4 is light for its size it's about18 times larger than Earth.
Scientist aren't exactly sure how TRES4 got so large.
One theory is that the planet's extremely close distance to its parent star is cooking up a lot of chemicals in its atmosphere which is trapping heat much like greenhouse gases.
This particular planet is only about five percent of the Earth's sun distance from its parent star so it's very, very close.
ln fact, it's so close it orbits its star every three and a half days.
So you can imagine how hot and howjust blasted with sunlight this thing must be.
Because the planet can't cool off, it can't shrink.
Because when it's very hot when gases are very hot, they expand so this might be contributing to keeping the radius of this planet so very large.
TRES4 may be a puffed-up planet but when it comes to sustaining life bigger planets don't offer prime real estate.
These giant planets really arejust gas.
There's no solid structure to them at all.
There's nowhere to stand on them.
So it's not a very likely place to find life 'cause life would have to continually be blown around in the atmosphere and that's a hard thing to evolve from.
This planet would not be a very habitable place because it's so close to its parent star.
lt's getting blasted with radiation from its sun so it would be a very hot and unpleasant place to be at least for humans.
TRES4 currently has the largest known radius.
However, the planet could be bumped out offirst place in the nearfuture.
Scientists are finding new planets basically every day almost at this point.
So it's quite possible that we will find another one that's even bigger than this particular planet any time.
ln addition to planets scientists are also discovering new asteroids all the time.
These are rocky bodies that didn't become planets and the largest one may exist in our galactic neighborhood.
ln our own solar system billions upon billions of leftover rocks that didn't become planets take refuge in the asteroid belt.
Some are as small as grains of dust and others are the size of nations.
Ceres was the first asteroid ever discovered and it remains the largest known asteroid to date.
Named after the Roman goddess of plants and harvest Ceres is about 600 miles in diameter so it's almost as large as the state of California.
Ceres is so big that it contains 25 percent of all of the mass in the asteroid belt.
Ceres is so big that ifyou took all the other asteroids in the asteroid belt and glued them all together they'd only be about two or three times bigger than Ceres.
Ceres' size sets it apart from the rest of the rocks in the asteroid belt.
lt would take the Apollo lunar rover10 days to drive around the asteroid at eight miles per hour.
But in addition to its size its other distinct feature is its round shape.
We have all these ldaho potatoes orbiting in the asteroid belt of the solar system most ofwhich are craggy chunks of rock.
Ceres is large enough, massive enough that its gravity has overcome the strength of the rocks that contain it.
And any time that happens, the shape becomes a sphere.
Because of its round shape, Ceres now holds a dual title.
The current definition of a dwarf planet is something that in fact is massive enough and has enough self gravity to form itself into a round shape.
And, in fact, since Ceres is round we also call it in addition to being an asteroid a dwarf planet.
We know only a little bit about the composition of Ceres right now.
We know that it's made primarily of rock but it may also have water ice and in fact, it could have clay inside it as well.
The Dawn Mission is actually gonna go to Ceres and enter into orbit around it and they'll bring a whole suite of instruments to bear on it so we should learn a lot more about the composition of this unusually large asteroid in our own solar system.
Ceres may be the largest asteroid in our solar system but it's a big universe out there.
lt's quite possible that as we go on to exploring other solar systems outside of our own that we may in fact someday find an asteroid larger than Ceres.
Our solar system contains some oversized objects.
The largest planet, Jupiter has the biggest moon, named Ganymede.
Planet Mars actually contains the largest volcano called Olympus Mons.
lt's 17 miles tall which makes it about three times taller than the biggest volcano we have on Earth.
lt's so tall that ifyou stood at the base of Olympus Mons you wouldn't be able to see the top due to the curvature of Mars itself.
So in our own solar system, the biggest things definitely have had a powerful shaping effect on the universe.
One might guess that the sun would take top honors as the largest thing in our cosmic suburb.
lt's a thousand times more massive than Jupiter.
But is there something bigger? The largest object associated with our solar system is the Oort Cloud.
And this is a very diffuse cloud of comets that literally extends about halfway out to the nearest star, Alpha Centauri.
Alpha Centauri is about four light-years away.
Astronomers estimate it would take the space shuttle hundreds of thousands ofyears to travel around the outer edge ofthe Oort Cloud.
The Oort Cloud is so dark and so distant that we really can't directly observe it but what we do know is that comets come in from every direction of the sky so there must be a spherical cloud of comets far away from us.
The origins of the Oort Cloud remain puzzling.
One theory is that it was formed early in our solar system.
As comets fell in towards the forming sun they were ejected into long orbits.
Over time, their orbits threw them out into a giant cloud.
lt's very far away and it's filled with icy remnants that havejust been left in basically the same state that theywere from right around the time when our solar system formed about four and a half billion years ago.
So they are, you could say, the archeological remnants ofthe formation of our solar system.
The universe is comprised of things both big and small.
But it's the large structures in space that challenge our understanding of how the universe works.
Although astronomers have found many substantial objects the quest to find even larger ones continues.
Astronomers are hoping to find new large planets new huge super clusters and learn more about the things that we've already seen.
As technology improves with better telescopes better detectors, newer surveys we will be able to see farther into space and therefore hopefully discover even bigger things than we already know about.
Now, see further than we've ever imagined beyond the limits of our existence in a place we call "The Universe.
" The biggest things in space are gargantuan beasts.
Each one is a heavyweight in its galactic division.
The universe is an unimaginably large place.
lt's so big it's really hard for human beings to actually comprehend things ofthese size scales.
On Earth and in the universe, size matters but it matters in different ways.
ln space, bigger is not necessarily better.
And oftentimes, the winners live large and die young.
They're the Mount Everests ofthe cosmos.
Astronomers aim their telescopes at them like paparazzi eager to capture images of their every movement.
They are the biggest things in the universe and their sizes are truly mind-boggling.
The good thing about being huge in the universe is that the universe is even huger than you are so there's plenty of space to stretch out and get your size measured among intelligent civilizations that are having a look.
The first thing you find out when you start studying astronomy is how darn big everything is.
Almost everything you're studying is so far beyond any kind of human scale that we're ever going to encounter in our normal lives.
The universe is brimming with gigantic objects.
Within our own solar system Earth is the fifth biggest planet but it's a hundred million billion times smaller than the largest stuff in space.
So what holds the coveted title as the biggest thing in the universe? Most astronomers agree it's the cosmic web an endless scaffolding of superclusters of galaxies surrounded by dark matter an invisible and mysterious form of matter that accounts for 90 percent ofthe universe's mass.
The largest thing in the universe you might even wonder if it's a thing at all it's a web of dark matter that fills the volume ofthe universe.
Dark matter is this matter that we can't even see.
lt doesn't emit any light but it is filled throughout the universe and there's structure in it.
Dark matter is something much more mysterious than most people know.
Literally, the stuff that makes me up dark matter isn't made of that.
l don't think you could smell it l don't think you could touch it.
lt simply has gravitational attraction.
The cosmic web of dark matter becomes visible when looking at the objects that fill it.
This cosmic web really is almost like a three-dimensional spider"s web.
At the very center of all the vortexes there are the superclusters clusters of thousands of galaxies and then filaments of galaxies connect them all the way across the volume of the universe.
The deepest, strongest gravity at the intersections of these weblike structures is where all the gas falls and that's where galaxies form-- clusters of galaxies form.
Butjust how big is the cosmic web? lf the Milky Way galaxy were the size of a poppy seed then the observable universe, everything we can see would be about the volume of the Rose Bowl stadium.
Now, that entire volume is filled with a cosmic web superclusters linked together from one side of the universe to the other.
The origins of the cosmic web remain uncertain but scientists think its initial seeds were planted in the Big Bang, the beginning of the universe.
During the Big Bang explosion the whole universe blew up, essentially and expanded very rapidly so the cosmic matterweb contains all of the original matter that was created during the Big Bang just blown up into the very, very large structures that we see today.
Scientists are actively trying to map out the cosmic web which spans the entire universe.
One way is to look at hot, x-ray-emitting gas and how it's contained by the gravity present in the dark matter.
Anotherway is to look at something called gravitational lensing, where light is bent by the gravity of the cosmic web and so we're able to sort of see the outlines of that cosmic web by the way it distorts the light that's behind it.
The cosmic web basically contains everything in the universe but some scientists question whether it's technically the largest object because the web isn't continuously connected throughout space.
The cosmic matterweb is not actually the largest gravitationally bound object in the universe because all the matter in the universe has expanded so vastly the force of gravity is not enough to keep it together in one area whereas superclusters of galaxies are actually gravitationally bound meaning that they have enough mass to produce enough gravity to hold them together over the passage of time.
Astronomers don't have a firm estimate but the cosmic web could be made up of hundreds ofthousands of superclustered complexes.
These are mega collections of galaxies gravitationally bound up to hundreds of millions of light-years across.
The universe is organized hierarchically.
Stars make up galaxies galaxies make up clusters clusters make up superclusters.
You could draw an analogy that a cluster might be the North American continent and a supercluster might be the association of cities on the North American continent cities on the European continent cities on the Asian continent, et cetera.
The current record holder for the largest supercluster of galaxies is called the Shapley Supercluster.
This dense region of galaxies is 400 million light-years long.
So it would take the fastest interplanetary spacecraft trillions ofyears to travel across it.
The Shapley Supercluster spans several constellations and is almost from our Milky Way galaxy.
l have here a small toy boat which is a replica of the Queen Mary which you can see here behind me.
And this little toy is about 4,000 times smaller than the real Queen Mary.
lfyou could just imagine that our own Milky Way galaxy that we live in is the same size as this toy boat then one of the most massive superclusters that we know about, the Shapley Supercluster would be the same size as theQueen Mary.
So the Shapley Supercluster would be about 4,000 times larger than our own Milky Way.
lt's one of the most massive things we know about in the entire universe.
Astronomers have known about superclusters since the 1950s but now they've determined their origin through recent measurements ofthe cosmic microwave background which is actual radiation left overfrom the Big Bang.
lt's been concluded that all superclusters including the Shapley Supercluster originated during the formation of the universe over13 billion years ago.
As the universe evolves and expands gravity is an attractive force so any region that has a little extra density there attracts more matter and more matter.
So, Shapley is a cluster that basically had the accumulation of many other little galaxies falling into it and that's how it's gotten so big over time.
lncredibly, scientists think the Shapley Supercluster may be even bigger than it appears.
ln fact, we may only be seeing a small fraction ofwhat's really contained within the Shapley Supercluster.
When the Wide-Field lnfrared Survey explorer launches we should be able to see about10 times farther away and hopefully, we'll be able to see the rest of the Shapley Supercluster to see if it is even more massive than what we already know about.
Superclusters of galaxies will stay together over time because they're gravitationally bound.
Gravity is holding them together.
So, even though the universe is expanding over time those superclusters of galaxies will stay together and they'll always keep orbiting each other.
We humans also live in a supercluster complex but it's less than half the size and about10 times less massive than the Shapley Supercluster.
Our Milky Way is part of a small, little cluster called the Local Group which is part of a larger cluster called the Virgo Cluster sort of on the outskirts ofthat.
So it's like your home address.
You live on this street, in this town in this state, in this country.
Similarly, the Milky Way has its larger and larger associations ofwhich it's a part.
Superclusters of galaxies are the most crowded neighborhoods in space but they surround equally big regions where almost nothing exists.
These bare spots are called voids.
Voids are the opposite of clusters.
lf clusters are where all the galaxies are voids are where all the galaxies aren't.
And you do see this kind offrothy, weblike structure of clusters and voids and clusters and voids.
So it's kind of like cities and countrysides cities and countryside.
The largest confirmed void in the universe remains Bootes.
Named after the constellation where it resides this near-empty space is a whopping 250 million light-years across.
That's equal to 2,500 Milky Way galaxies placed side by side.
Look out into the cosmos in any direction and you'll see something.
You'll see stuff, you'll see galaxies you'll see gas, dust, you'll detect dark matter.
Everywhere you look, there's something.
Yet here's this giant hole with nothing in it.
The Bootes Void, which was discovered in 1981 is almost completely devoid of galaxies.
A newway to search for even largervoids may be possible by precise measurements of the temperatures of the cosmic microwave background radiation.
Subtle cold spots in this radiation could locate the directions of large distant voids.
The story of theirformation is basically the reverse of how superclusters form.
The voids must have started out in the first microsecond ofthe Big Bang as slightly low-density regions.
But with time, they became less and less dense.
All ofthe matter flowed away into the sheets and filaments leaving the voids emptier and emptier of matter until today, there is almost nothing but a few little dwarf galaxies in some of these voids.
Voids and superclusters are just some ofthe big things contained in the even larger structure called the cosmic web.
But the web also holds other immense objects including colossal bubbles that might hold missing clues to the formation of galaxies.
The universe is packed with monstrous things.
Researchers have recently discovered giant clouds of gas that resemble something out of a horror movie.
These mysterious objects are called Lyman-Alpha blobs.
My personal favorite biggest objects in the universe are the Lyman-Alpha blobs an unpredicted, unexpected phenomenon where you're catching a galaxy in the first phases of its formation and collapse.
A Lyman-Alpha blob is very much like this expanding soap bubble except, in the case of the soap bubble it's the airwhich is making it fill up.
A Lyman-Alpha blob is expanding because of heat.
A lot of energy has been injected into this gas to make it heat up.
And when you put all that energy into a gas it inevitably tends to puff up and expand exactly like an expanding bubble.
ln the case of a Lyman-Alpha blob, it's being puffed up by heat and maybe also by the ultraviolet radiation from newly formed stars.
The largest known Lyman-Alpha blob is a colossal, amoeba-shaped structure that resembles a giant greenjellyfish.
lt's 200 million light-years wide and is located in the constellation Aquarius.
When we're looking at the Lyman-Alpha blob we're seeing gas that sort of spread amongst these very first stars and galaxies.
lt's kind of an amorphous shape of about 30 separate little blobs inside of it.
lt's very large and very massive.
The whole structure is about of our own Milky Way galaxy.
The Keck and Subaru telescopes in Hawaii contain special filters that are able to see this faraway blob which spreads out along curvy tentacles.
Scientists estimate that the largest Lyman-Alpha blob was formed about almost two billion years after the Big Bang.
The observational technique we use to see that gas refers to a very specific color of light, emission of light that's called Lyman-Alpha.
So you hear a phrase Lyman-Alpha blob because ifyou take an image of the sky through a filter that gives you only that Lyman-Alpha light that very special wavelength of light you'll see a little blob on the sky.
Lyman-Alpha blobs are perhaps precursors to the galaxy clusters we see today.
Within these gigantic bubbles may exist cocoons that will one day spawn new galaxies.
The Lyman-Alpha blobs are probably a fairly special short-lived phase in the evolution to creating a galaxy.
l would expect that most of them are going to collapse and form young galaxies in the next100 million years or so of their lives so it's a special phase just when a galaxy is beginning to pull itself together.
The search in the universe for Lyman-Alpha blobs isjust beginning.
We'll undoubtedly find many more ofthem and even perhaps some larger ones in the future.
Stay tuned.
Lyman-Alpha blobs may hold the answers to the formation of individual galaxies which are gravitationally bound systems containing stars, gas, dust, and dark matter.
At least100 billion single galaxies exist in the observable universe.
They range in size from ten thousand to millions of light-years across.
Galaxies, these titanic collections of stars l think of them as cities having been born in one myself not only a galaxy, but also an actual city a native of New Yorkwhere everyone is crowded together.
Galaxies are sort of how matter has organized itself in the universe.
ln the competition for largest single galaxy in the universe sizing up a winner is challenging.
The problem in saying what's the largest galaxy is in deciding where they end.
Galaxy does not have a sharp edge.
ltjust gets thinner and thinner as you go further out.
lt's exactly analogous to saying where is the end of a very large metropolitan area? Where is the end of Los Angeles? You can go out 50 miles and you'll still find a fairly high density of suburbs.
The suburbs of a big galaxy like the Milky Way extend out very, very far, more than 100,000 light-years.
And with a giant galaxy, those suburbs extend out hundreds of thousands of light-years.
Since scientists can't determine a clearwinner several galaxies share the title as biggest.
They're called cluster-diffused or CD galaxies and they sit in the centers of rich clusters of galaxies.
lfyou think about the cosmic web as being sort of like a three-dimensional spiderweb well, then, the spiders lurking in the middle ofthe web are these monstrous CD galaxies, as we call them.
These galaxies can have masses that are in some cases maybe 10 times or 20 times the mass of our own Milky Way.
These CD galaxies are the largest galaxies in the universe.
For example, lC-1101 sits in the center of a galaxy cluster called Abell-2029 and it's six million light-years across.
Compare that to our own Milky Way that's100,000 light-years across.
lt's a really big galaxy.
lt's 60 times the size of our Milky Way.
CD galaxies are elliptically shaped as opposed to a disc structure like our Milky Way.
This is because they've achieved their size by bulking up on other galaxies through galaxy mergers.
You may have heard the phrase "galaxy cannibalism" where one galaxy eats another.
That goes on all the time in clusters of galaxies.
And so, sitting usually down at the very center of a massive cluster, you'll find one big galaxy.
These CD galaxies have so much mass that they are the 800-pound gorilla wherever they are.
You see little galaxies maybe orbiting around them but, basically, it's eaten up everything nearby.
The largest galaxies may be six to 20 million light-years across.
However, there are other objects even larger.
They're called radio lobes.
Stretching out from both sides of the galaxy these immense structures are actually hurling jets of charged particles that emit radio waves.
So we're here in this auto body shop where l'm gonna use these two torches to simulate radiojets coming out of opposite sides of an accretion disc swirling around a supermassive black hole.
So in the visible you see a small blue flame coming off ofthe torch.
But in the infrared you can see that the heat from the torch extends much, much further out.
Similarly with the radiojets what you see in the optical is actually quite different from what you see in radio waves.
A typical lobe might be as the lobe spreads out on both sides of the galaxy.
That's about twice the size of the Milky Way galaxy's disc.
Astronomers think radio lobes are powered by supermassive black holes located in quasars.
These are the luminous centers of most active galaxies.
Thejets of radio energy that come from a giant black hole and make these enormous radio lobe structures are very closely related to quasars.
ln fact, in some cases, you can see a low-power quasar in the center of the galaxy and then it's surrounded by these giant lobes to either side.
They have been blasted out by very high-energy jets of electrons that are basically moving at almost the speed of light.
And they are blasted out, probably from the north and south poles of the spinning black hole.
The radio lobes depend on matter going down the black hole.
As matter goes down the black hole some of it gets accelerated up into these lobes.
So the size of the lobes has something to do with the history of how much matter the black hole has actually fed on.
And so over time, they'll change size.
Radio telescopes have surveyed the universe and determined the largest known radio lobe.
The undeniable record holder is located in the galaxy named 3C236 which is in the constellation Leo Minor.
ltsjets span 40 million light-years across.
Scientists don't understand why some active galaxies form thesejets and others don't, but one thing is certain radio lobes will not last forever perhaps for only a few million years.
So, just as this torch will eventually run out of gas and shut itself off thejets from a radio galaxy will eventually die as well.
When the black hole has consumed all of the material in its immediate vicinity there'll be nothing left of the accretion disc to get shot out along the magnetic field lines and thejet will die.
lf black holes are the producers of these gigantic radio lobes then what is the largest black hole in the universe? Scientists are currently placing bets on the winner.
When it comes to the biggest things in the universe some black holes earn a place in the record books.
A black hole is a region of space where the pull of gravity is so immense that nothing can escape it, not even light.
There are billions upon billions ofthese black monsters prowling the universe.
They come in two size categories.
Most ofthem are the stellar mass black holes which are about five to 100 times the mass of our sun.
And then there are supermassive black holes that are millions to billions of times the mass of the sun.
We have the supermassive black holes the kind that we seem to be finding in the centers of every galaxy where we've had the resources to look.
Havoc is wrought upon your environment ifyou're a star orbiting close to one ofthese supermassive black holes in the centers of these galaxies.
Black holes are not physically large regions but when measuring their mass they become top competitors in the galactic heavyweight division.
The center of our Milky Way we know that there's a black hole that's about maybe three million times the mass of our own sun.
And yet, because black holes are so incredibly dense the actual size of the black hole is still fairly small but incredibly, incredibly powerful gravitationally.
As their name suggests, these black beasts are essentially black because no light can escape them.
So one can only be observed when its gravity affects something else in space such as a passing star orwhen it's gorging on matter around it.
So what is the reigning black hole champion? The current record holder for the largest black hole appears to be in the incredibly luminous quasar which has the prosaic-sounding name HS1946+7658.
Why do l say it's the largest black hole? Because we know it is the most luminous quasar in the universe that's been found so far.
The black hole that's holding it together that's producing the energy needs to be about10 billion times the mass of the sun.
That corresponds to a black hole which is larger than our entire solar system.
ln fact, it'sjust out there to remind us how bizarre a seemingly simple force like gravity can actually be.
The largest supermassive black hole wields power in the center of a galaxy but there are other big luminous objects in the universe.
ln fact, there are some that seem to exist everywhere we look.
When we glance into the nighttime sky we see stars, twinkling dots of light that are actually luminous balls of plasma.
Although they may seem small from Earth stars come in a variety of sizes from red dwarfs which are about1/12 the mass of our sun to blue-white super giants that can get as big as 150 solar masses.
Our Milky Way holds 100 billion stars including our sun which is over 300,000 times the mass of planet Earth.
And this cosmic beacon is a literal powerhouse in our solar system.
This natural gas power plant produces about You know, that's enough to power a few hundred thousand homes.
But that's only a tiny fraction of our sun's energy output.
The sun's power is about two billion, billion times the amount of this plant.
So even in spite of its distance the sun is able to warm our entire planet.
Even so, our sun isn't the largest or the most powerful star by a long shot.
The most powerful stars are about a million times as powerful as the sun.
So ifyou wanted to compare that with the Hoover Dam you would need Hoover Dams per person on the planet to generate that much power.
There's really no human scale to imagine this power output.
The largest and most powerful stars that produce this kind of energy are called red hyper giants.
That's a class of stars that's even larger than super giant stars.
So typically, stars like our sun are fusing hydrogen into helium to make their energy.
But hyper giant stars have already exhausted all the hydrogen in their core and they're fusing hydrogen into helium in the outskirts around the core and that makes them extremely hot and energetic and all that energy causes the star to swell up and so the star ends up with a very large surface area surface areas of the size ofthe Earth's orbit or even bigger.
Within the hefty field of red hyper giants VY Canis Majoris appears to have the largest diameter.
lt's 2,000 times wider than our sun and consequently, it would take the world's fastest race car to circle it once.
This stellar champ lives about in the constellation Canis Majoris.
lfyou replace the sun with VY Canis Majoris ifyou put this hyper giant star where the sun is its radius would extend out past Saturn's orbit.
lt would be about nine times as farfrom the sun as the Earth is so this is a much broader in diameter star than our sun is.
Astronomers determine the radius of such a large star by looking at its temperature.
We use measurements ofthe temperature of the star's surface which we can get from the color of the star and then we will also measure the total power output or luminosity of the star.
And by combining those, we can determine what its total surface area is of the star and from that, we get its diameter.
Now, that assumes that you can measure its luminosity fairly well and that you know something about its temperature from its color.
Most of the time theyjust simply appear as pinpoints of light and it's impossible to actually resolve it.
Although there are new instruments now called interferometers which are capable of resolving even very tiny point sources, like stars.
And in some cases there have been direct measurements of stellar diameters.
VY Canis Majoris will not be a title holderforever.
The red hyper giant is losing mass at the rate of almost 30 Earth masses or more peryear.
The largest stars in the universe like VY Canis Majoris are actually dying stars that as stars begin to die they burn their nuclearfuel much less stably.
They puff out over time.
VY Canis Majoris is probably only a few million years old.
Stars that are as massive as it is don't live very long.
They use theirfuel up at prodigious rates then they swell up into this hyper giant state and only live there for a few hundred thousand years a very short time scale and then they will explode.
VY Canis Majoris might have the largest diameter but when it comes to possessing the most mass there's another star that tips the scale.
ln the wide world of stars there are many contenders vying for the title as the largest in the universe.
But when it comes to stars big can mean two different things.
When you talk about the biggest star you can mean one of two things.
You can either mean the star that has the largest diameter oryou might mean what its mass is.
The mass is a measure of how much stuffyou have.
lt's sort of like yourweight when you step on a scale how much matteryour body is made of.
According to some astronomers the most massive star is located in our Milky Way galaxy.
lts part of a binary star system known as A1 which is actually two stars that orbit each other once every four days.
We find there that one of the stars appears to have a mass of about115 times the mass of the sun and the other star is also enormous about 84 times the mass of the sun.
So both stars in this binary are among the most massive stars that we have ever measured.
There may be more massive stars than the combination in A1 in this star cluster but that's the most massive that we've been able to measure directly.
These massive stars will live full, but short lives.
Massive stars are hugely luminous.
Sometimes they can outshine millions of stars in their neighborhood but at a cost.
The cost is they will run out offuel faster than everybody else and when they die, they die spectacularly.
They explode their guts and scatter it across the galaxy.
So the cost of living a high-mass life a high-luminous life the cost of living in the fast lane is that you explode at the end ofyour life.
A bright star may burn out faster and die sooner but at the same time those hot stars are cooking up elements that are essential for life.
So without really massive stars, we wouldn't be here because you wouldn't get the iron in my blood and the calcium in my bones.
All ofthose things are formed only in the most massive stars.
We humans need essential elements from massive stars but we also need a planet with a firm surface to stand on.
Planets come in two size groups large gas giants like Jupiter and small rocky terrestrials such as Earth.
ln our own solar system Jupiter is the largest planet while Earth trails in fifth place.
Yet, even though Jupiter reigns supreme in our galactic zip code it's not the biggest planet in the universe.
The largest planet with a well-known radius is called TRES4.
lt's named after the Trans-Atlantic Exoplanet Survey that discovered it in the constellation Hercules in 2006.
TRES4 is unusually large for its mass.
We can actually directly measure its radius and this particular planet has an unusually large radius.
lt's about 70 percent bigger than Jupiter yet it has only about 80 percent of Jupiter"s mass.
That's about the same density as cork or even whipped cream.
lfyou look at Earth it's a rocky planet, very dense and then even the gas giant planets like Jupiter are compressed gas and water and other chemicals very tightly compressed.
This thing, TRES4, is like a marshmallow.
Although TRES4 is light for its size it's about18 times larger than Earth.
Scientist aren't exactly sure how TRES4 got so large.
One theory is that the planet's extremely close distance to its parent star is cooking up a lot of chemicals in its atmosphere which is trapping heat much like greenhouse gases.
This particular planet is only about five percent of the Earth's sun distance from its parent star so it's very, very close.
ln fact, it's so close it orbits its star every three and a half days.
So you can imagine how hot and howjust blasted with sunlight this thing must be.
Because the planet can't cool off, it can't shrink.
Because when it's very hot when gases are very hot, they expand so this might be contributing to keeping the radius of this planet so very large.
TRES4 may be a puffed-up planet but when it comes to sustaining life bigger planets don't offer prime real estate.
These giant planets really arejust gas.
There's no solid structure to them at all.
There's nowhere to stand on them.
So it's not a very likely place to find life 'cause life would have to continually be blown around in the atmosphere and that's a hard thing to evolve from.
This planet would not be a very habitable place because it's so close to its parent star.
lt's getting blasted with radiation from its sun so it would be a very hot and unpleasant place to be at least for humans.
TRES4 currently has the largest known radius.
However, the planet could be bumped out offirst place in the nearfuture.
Scientists are finding new planets basically every day almost at this point.
So it's quite possible that we will find another one that's even bigger than this particular planet any time.
ln addition to planets scientists are also discovering new asteroids all the time.
These are rocky bodies that didn't become planets and the largest one may exist in our galactic neighborhood.
ln our own solar system billions upon billions of leftover rocks that didn't become planets take refuge in the asteroid belt.
Some are as small as grains of dust and others are the size of nations.
Ceres was the first asteroid ever discovered and it remains the largest known asteroid to date.
Named after the Roman goddess of plants and harvest Ceres is about 600 miles in diameter so it's almost as large as the state of California.
Ceres is so big that it contains 25 percent of all of the mass in the asteroid belt.
Ceres is so big that ifyou took all the other asteroids in the asteroid belt and glued them all together they'd only be about two or three times bigger than Ceres.
Ceres' size sets it apart from the rest of the rocks in the asteroid belt.
lt would take the Apollo lunar rover10 days to drive around the asteroid at eight miles per hour.
But in addition to its size its other distinct feature is its round shape.
We have all these ldaho potatoes orbiting in the asteroid belt of the solar system most ofwhich are craggy chunks of rock.
Ceres is large enough, massive enough that its gravity has overcome the strength of the rocks that contain it.
And any time that happens, the shape becomes a sphere.
Because of its round shape, Ceres now holds a dual title.
The current definition of a dwarf planet is something that in fact is massive enough and has enough self gravity to form itself into a round shape.
And, in fact, since Ceres is round we also call it in addition to being an asteroid a dwarf planet.
We know only a little bit about the composition of Ceres right now.
We know that it's made primarily of rock but it may also have water ice and in fact, it could have clay inside it as well.
The Dawn Mission is actually gonna go to Ceres and enter into orbit around it and they'll bring a whole suite of instruments to bear on it so we should learn a lot more about the composition of this unusually large asteroid in our own solar system.
Ceres may be the largest asteroid in our solar system but it's a big universe out there.
lt's quite possible that as we go on to exploring other solar systems outside of our own that we may in fact someday find an asteroid larger than Ceres.
Our solar system contains some oversized objects.
The largest planet, Jupiter has the biggest moon, named Ganymede.
Planet Mars actually contains the largest volcano called Olympus Mons.
lt's 17 miles tall which makes it about three times taller than the biggest volcano we have on Earth.
lt's so tall that ifyou stood at the base of Olympus Mons you wouldn't be able to see the top due to the curvature of Mars itself.
So in our own solar system, the biggest things definitely have had a powerful shaping effect on the universe.
One might guess that the sun would take top honors as the largest thing in our cosmic suburb.
lt's a thousand times more massive than Jupiter.
But is there something bigger? The largest object associated with our solar system is the Oort Cloud.
And this is a very diffuse cloud of comets that literally extends about halfway out to the nearest star, Alpha Centauri.
Alpha Centauri is about four light-years away.
Astronomers estimate it would take the space shuttle hundreds of thousands ofyears to travel around the outer edge ofthe Oort Cloud.
The Oort Cloud is so dark and so distant that we really can't directly observe it but what we do know is that comets come in from every direction of the sky so there must be a spherical cloud of comets far away from us.
The origins of the Oort Cloud remain puzzling.
One theory is that it was formed early in our solar system.
As comets fell in towards the forming sun they were ejected into long orbits.
Over time, their orbits threw them out into a giant cloud.
lt's very far away and it's filled with icy remnants that havejust been left in basically the same state that theywere from right around the time when our solar system formed about four and a half billion years ago.
So they are, you could say, the archeological remnants ofthe formation of our solar system.
The universe is comprised of things both big and small.
But it's the large structures in space that challenge our understanding of how the universe works.
Although astronomers have found many substantial objects the quest to find even larger ones continues.
Astronomers are hoping to find new large planets new huge super clusters and learn more about the things that we've already seen.
As technology improves with better telescopes better detectors, newer surveys we will be able to see farther into space and therefore hopefully discover even bigger things than we already know about.