(speaker) Now would probably be a pretty bad time for me to admit that I have  a bit of a fear of heights.
How tall are we here?
How high up?
(speaker)  We're just at 30 meters now.
30 meters.
So.
[sighs] (host)  High in the canopy  of a forest in the Pacific Northwest, or out on the deadly  plains of the Serengeti...
Right now, there's a lion staring at me.
It's very difficult  to talk to you.
(host)  ...two places that probably  couldn't seem more different.
We've just come upon a group of lions, and what I can only say is approximately  one third of a wildebeest.
(speaker)  Yeah, they've been-- they've been at it.
(host)  Yet there's this incredible  principle of life that ties them together.
The thing is, to see it, you've got to stop looking  at nature like this... and start looking at it  like this.
[light upbeat music] Nature is full of drama and cuteness and beauty and just plain weird things.
But what if predators  and prey and plants are just really cool ways of moving nutrients, elements, and atoms around?
What if that's the real circle of life?
Whoa.
I mean, I never really thought of it like that, but it makes sense.
I mean, I think about dead stuff and weird things all the time.
But like elements and chemicals and nutrients or whatever, you know, my one semester of chemical engineering in college says, "Yeah, that's cool," but doesn't it kind of take the fun out of everything to think of it as base elements, just moving from here to there?
I don't think so, actually.
Not if you look at it this way.
(Joe) Okay, so a couple episodes ago, we talked about how wildebeest  make one of Earth's most dramatic annual  migrations, right?
As they travel up from these  lush rainy season grasslands to their dry season refuge hundreds of miles to the north, a million and a half  wildebeest have to cross a seriously dangerous obstacle, the Mara River.
So they mass up along the shores, just waiting, nervous, until suddenly an avalanche of hooves descends into the river.
It's chaos.
The river itself  is dangerous enough, but what's in the water  is even worse.
As the survivors make it ashore, the river is just littered  with bodies.
And some of those are from the crocodiles, but even more of them are from mass drownings.
Just realized  someone should invent, like, a wildebeest life jacket or something.
It would make this so much easier.
It'd be entertaining when a crocodile gets one, though, 'cause it'll just like-- I love this.
Give me a front row seat.
I want to see this for myself.
(Joe)  Every year, thousands of tons of wildebeest bodies are put into this one river.
Now the soft tissue decomposes  pretty quickly, right.
But half of a wildebeest's  biomass is bones and those take a lot longer  to break down-- months,  even years sometimes.
And locked inside  of those bones are nutrients-- stuff like calcium,  phosphorus, carbon, nitrogen-- elements that other organisms  in the ecosystem need to grow.
We're talking up  to 50 blue whales worth of nutrients and biomass seeping into this river  every year and then flowing downstream to  other parts of the ecosystem where it might end up in, say, grass, grass that can become  another wildebeest.
Every single ecosystem  on Earth depends on cycles just like this.
Life is just atoms, then, moving between living and non-living things, and maybe I'm just a collection of nutrients?
I can't be the only one who's a little weirded out by this, can I?
I mean I-I love this sort of thing.
It's the death that drives everything else in nature.
Joe, I need to see more of this dead stuff.
Coming right up.
So back in the Serengeti, Jahawi and I set out to explore the shore  of this waterhole.
What I didn't realize  is that what we found there would help tie together so many scenes of life  and death we'd encounter  on the rest of our journey.
One thing I was not prepared for was just how many bones there are just everywhere and hooves.
I know.
These used to belong to somebody.
I mean it's complete carnage everywhere.
So you've got the lions that'll take down the wildebeest and start eating.
Now depending on how much noise was made, that could attract hyenas.
(Joe) So hyenas, they got this reputation for being these  vicious scavengers.
I mean, they're always happy  to take a meal from somebody else's  gross leftovers, right?
But I think they've gotten  a really bad rap.
Yeah, thanks, Disney.
Boo!
Hyenas are awesome.
(Joe)  They really are.
I mean, they're social and highly intelligent  creatures, right?
And super successful predators in their own right.
And they have one of the highest kill success rates of any carnivore, and not only that they're strong enough  and creative enough that they can even push lions off of a kill.
There is a lion and a hyena.
Lion and hyena.
Wow.
So we're coming up on lion and hyena.
(Joe)  A pride of lions has killed and eaten most of a zebra and the smell of this kill has  attracted a pack of hyenas.
At first, the smaller hyenas  are outnumbered, but soon more arrive and aware of their numbers or the lion's full bellies, they sense they may have the upper hand.
I think you mean upper paw.
Eh!
(Joe)  Very, very funny, Graslie.
Where was I?
The hyenas make their move.
(Jahawi)  They're getting excited  now, you can see.
So their tails will start to rise and look, they start pulling.
(Joe) The lions retreat and the few choice prizes that remain are the hyenas' to squabble over.
But in the vicious competition  for resources, at least one of them  knows how to get "a head."
Blugh!
Joe!
That's bad, that's bad.
The head.
Like a head.
No, I--yeah.
We get it.
We get it.
Not sorry.
There's not much left.
I mean, imagine, all those lions would have  just eaten so much, and when the other hyena  came in, they were literally  scrapping for bones.
(Joe) "I've got the pelvis.
You can't catch me."
(Joe) So back at the waterhole, the day before, I noticed something kind of weird, that all of the bones  that were left there were just things like skulls  and backbones and ribs.
All of the long bones that were full of that delicious marrow, they were nowhere to be found.
(Trace) Fun fact, maybe related: hyenas have a stronger  bite force than any African carnivore.
I mean, I knew that, 'cause hyenas are sick.
And with that hyenas' bite force, they can actually crack that bone and get into there, and they will actually crush the bone and eat it.
If you look at that, kind of shows it straight through.
So this--this is definitely hyena.
'Cause they can digest the bone.
Yeah, their stomach is so acidic that it literally just breaks down the bone.
Wow.
I mean the sound that hyenas make, the way that they move, they are a little bit silly, but they have this incredibly important role out there in this ecosystem, cleaning up  all of these kills.
But anyway,  when they were all finished, we headed over to see  what was left.
Wow, that is pretty gross.
There's nothing left, except a big bloodstain on the Serengeti.
Yeah.
But even that will return back to the ecosystem.
I mean, already, as we're standing here, like, I just saw a butterfly land in this gory kill scene, but there's salt, there's water.
I mean, there's so many levels of nutrients and there's a--  there's an organism that's specialized  for every one of them.
(Jahawi)  This just goes to show you just how many different species one kill can support.
And that's why, you know, the plains  aren't just littered with dead rotting bodies.
The smell is something.
Yeah, I could--I could-- I could get farther away.
How do you feel about breakfast?
(Jahawi) I think it's about time.
(Joe) Yeah, I'm hungry.
What do you eat after you see that?
Oh, I mean, bacon.
I think it sounds pretty good.
You guys are weird.
So, okay, Joe, but hyenas aren't the only thing recycling all this dead stuff.
That's exactly right.
There are a bunch of other animals who help recycle all these dead nutrients back into the ecosystem.
(Jahawi)  I mean, this is just crazy.
(Joe) This is absolute chaos.
What you're hearing  in the background, we've just come across a kill.
Kind of hard to tell  what's under there, because there's like a hundred vultures in a pile on top of what used to be an animal.
Yeah, I mean, it's just, this whole area's  covered in vultures with more of them coming in.
I mean,  they're like grumpy old men all just arguing with each other.
And the marabou stork  looks like he's just presiding over this--the proceedings.
(Joe)  He's like the referee.
Gentlemen, keep it clean.
A neat thing about vultures is they have a bunch of different names for groups of them.
So vultures in flight,  they're called a "kettle."
Once they land they're called  a "committee."
And then  when they're feasting, that is called a "wake."
(Joe)  Why do you know so much about vulture group terminology?
You holding out on us?
Just know things, Joe.
(Joe)  Bald head, hooked beak.
A vulture is basically made for reaching parts  of a carcass that large predators can't.
(Jahawi)  So your bigger vulture species can sort of rip open skin and stuff like that.
Your smaller ones will be really getting their heads in there.
In there?
(Jahawi) In there.
(both)  Like in there.
(Joe)  I mean, somebody's got to eat every part of this, right?
So they've all specialized to get at every bit of nutrients that they can out of something like this.
This is the birdsong  of the Serengeti.
The sound of screeching  hungry vultures.
I mean, it's very musical.
Musical the way that a garbage truck is music.
When those vultures fly off  into some tree and later, you know,  make a poo, well, that nitrogen  and that carbon, even iron, that used to be  inside of that carcass, it gets dropped back  into the ecosystem.
But in this kill- or-be-killed environment, there are still more bones left behind than these scavengers can clean up, but even those are broken down over months and years.
So you've got different insects that can come in and start trying to break it down, and then also to the microbial level.
(Joe) It looks like part of a-- part of the--a backbone here, like a vertebra.
Yeah.
(Jahawi) I mean, there are minerals in here.
And so once this bakes in the sun, it's gonna start cracking, and when it starts cracking, that's when it can start releasing the nutrient.
But the incredible thing is,  sometimes you find giraffe chewing on old bones.
I thought they only ate leaves!
(Joe)  Yeah, they do that  to get minerals that they don't get  from their diet, like phosphorus and calcium that's not in  those acacia leaves they love to munch on so much.
(Trace)  Like a vitamin lozenge.
(Joe)  So weird.
So weird.
Anyway, weather and microscopic organisms take over and eventually, every part of this creature makes its way back into what I think is the most underappreciated and overlooked part of this entire ecosystem.
I mean, it's right under our noses, or our toes, I guess.
But what happens down there  in the soil, I mean, it's literally the foundation of every terrestrial ecosystem.
Take fungi, for instance.
They live in these  symbiotic relationships with the roots of plants.
And so they feed  the plants nutrients and help them get access to water, and in an exchange,  they get some of that fuel; the products  of photosynthesis.
Out on the Serengeti, fungi only make up less than 1% of all the living biomass, but they put back twice as many nutrients into the ecosystem as all of the animals combined.
And microbes!
I mean, the air is what, 78% nitrogen?
But without special microbes  in the soil that convert that nitrogen  into forms that plants can actually use, I mean, life on this planet as we know it wouldn't even be possible.
And without dung beetles, I mean, the Serengeti would be  literally knee deep in you know what.
Scientists once counted  16,000 dung beetles and other poop eating bugs in just one pile of elephant dung.
It was gone  in two hours or less.
And in just 100 meter by 100 meter square area, out there on the Serengeti, dung beetles can bury more  than a ton of poop every year.
And termites!
All the termites  out there in the Serengeti probably outweigh the mammals and they're burying just unimaginable amounts of dead plant matter down there in their  underground little fungal farms and recycling  that back into the soil.
It's amazing.
In a place like the Serengeti, there's so much drama  and action and death happening up there  on the surface, but what happens on Earth in a big way depends on what happens in the Earth.
I just--I just get really excited about soil sometimes.
The question I still have is, how do scientists study this stuff?
Because, you know, we don't actually have special goggles we could put on to, like, let us see all the elements and atoms moving around in these wild places, and nature isn't a tidy laboratory environment.
You can't put an ecosystem in a test tube and study it.
I mean, but what if you could?
I just got back from visiting  this really cool long-term research program  in Oregon at this place called the H.J.
Andrews Experimental Forest.
Wait, wait, wait, wait, wait, wait, wait.
What--an experimental forest?
Are the trees, like, wearing lab coats, with tiny beakers swirling around and-- They're out there filling out lab reports and with goggles on?
Stop.
If scientists want to study  a system as complex and sprawling as a forest,  they can't do that indoors, so they go to outdoor labs  instead, like the Andrews forest.
Temperate rainforest like  these in the Pacific Northwest are home to thousands  of species.
And a big question that scientists have is, how do essential nutrients-- those elements like carbon  and phosphorus and potassium-- how do they get cycled  through these intricate webs?
I mean, it might seem less  chaotic than the Serengeti but the characters  in this drama are the same.
They're decomposers and scavengers.
And someone who's been to Africa, uh, one time, there's no hyenas in the forest, Emily, like, doing this scavenging?
So I'm talking about mulch munchers, and microscopic things happening down  in the understory.
But to understand all of that, we actually need to start up  there in the canopy.
(Emily) Is this our friend today?
(speaker) This is our friend.
(Emily)  That's my buddy Mark.
He's the Director  of the Andrews Forest and he's taking us up.
Wow, it's a tall tree.
That's a tall tree.
Most of these old Douglas fir in the stand are 450- to 500-year-old.
Wow, that's amazing.
(Mark)  They've seen a lot of--a  lot of floods, a lot of fires.
(Emily) They've stood--literally stood the test of time.
That's really high up.
[chuckles] My camera can't even zoom in to the top of the tree.
Oh, boy.
This gonna be fun.
(Mark) This is the most awkward part.
(Emily) I don't think anybody could make this stuff look cool.
Now would probably be a pretty bad time for me to admit that I have a bit of a fear of heights.
How-how--how tall are we here?
How high up?
(Mark)  We are just at 30 meters now.
(Emily) 30 meters.
[sighs] I'm all right.
We're gonna keep going up.
I feel for you-- heights can be scary.
But why are we going up in the tree in the first place?
They want to understand how nutrients move from the atmosphere  to the canopy and down to the forest floor.
So you got to start  at the top.
I mean, there's a certain kind  of lichen called "lungwort."
It grows all the way  up these trees and has a unique ability to pull nitrogen out of the air.
So when the lichens eventually  fall to the forest floor and decay, the nitrogen  goes back into the system.
Lichens.
I'm "likin'" this.
Somebody put Joe on mute, please.
Somebody?
Never heard that joke before.
Okay, beyond just wanting to make a personal visit to see our cool lichen friends, it turns out that this tree is actually  a tricked-out science lab.
It's got different instruments  all up and down the trunk.
So they're measuring things like rainfall, humidity, wind, tree stress, even things like microclimates that exist  at different heights.
It's amazing what kind of life you find up there and all the way up there, as high as we were, there were, like, tiny ants crawling on some of the cables  for the scientific equipment.
And to know that it just lives  its entire life, literally 12 or 14 stories above the forest floor.
Okay, here's the twist.
There's another key element at play in the forest but you're not gonna find it on the periodic table.
It's the element of time.
And all of the forest's  vitality is fed by the slow,  slow decay of its life.
So early on there became an interest in the Andrews forest about the fate of trees that had died.
That's Dr. Mark Harmon, forest ecologist/ tree whisperer.
We tend to think of a tree when it dies, it disappears from our mind, but it doesn't disappear from the forest unless we take it.
(Emily)  Yeah.
(Mark Harmon)  It can persist  for a really long time as a home for organisms, as a place to get food, as a structure that affects the physical nature  of the forest.
And so there became this  realization that dead trees could potentially be a important part of a forest.
I just realized, I have no idea how long a tree takes to disappear.
How do you even begin to study this?
Yeah, so in the 1980s, Mark and some other scientists started dumping cut trees in  different spots in the forest, and they started measuring  their shapes, sizes, and densities, and they kept going back, taking more measurements to see what was changing.
They've been doing this  for 40 years and the experiment is  projected to last until 2185, 200 years after it was started!
Whoa!
But that totally makes sense.
I mean, if things are happening so much slower here than, say, the Serengeti, I mean, this is the kind of study you're gonna pass on to your grandkids, I guess.
Ah, yes, the age old question, when the tree falls in the woods and nobody's around to document that event, how long do we know for it to decompose?
That wasn't a sentence.
No, it wasn't.
Exactly, it's all about decay.
A live tree is home  to lots of other organisms like birds and mosses  and lichens that live on it.
But in general, a tree doesn't  like stuff living in it.
In this study, we're starting to look at the other part, the other life of a tree, which is when it's dead.
So it has this thick bark because it's preventing all these organisms from growing in it.
Now when it dies, those rules are off.
Free game.
The mulch munchers.
The mulch munchers basically rule the world.
I love the phrase, "mulch munchers."
It sounds like a squishy superhero group.
Mulch munchers, assemble!
They're the esteemed detritivores of the undergrowth, here to save the day.
So these forest recyclers,  they're not big, munchy things like hyenas;  they're millipedes and molds, which frankly, I think are even cooler.
That's a fact.
They have lots of weirder things, frankly.
Yeah, tell me more.
(Emily)  Like junk coming out  of their heads, literally.
Millipedes' fourth leg segment is actually their genitals, just in case you needed an extra fact.
I have--I have several questions.
(Emily) So how long do you think it takes a tree to decompose?
(Joe)  Um, that's a good question.
Twenty, twenty-five years?
I'm thinking a lot longer, like 70, 80 years.
You guys aren't even close.
A Douglas fir might live for 300 or 400 years and take just as long  to decompose and species with super dense  wood like red cedars, they might live a thousand years and then take another  thousand years to decompose.
They're naturally rot resistant, which is why people like  to build stuff out of cedar.
It's impressive to think of all of the world events that have happened while this tree was growing here stationary.
I mean, we've got world wars, civil wars, the European colonization of America, the Sistine Chapel being built and painted, and all of this is happening on our human time scale, completely different than the magnitude of this organism's life.
So the point is that things are happening, but they're happening slowly.
And as a tree decays, scientists like Mark have broken it down into the five stages of log decomposition.
Decay is a--and decomposition is a continuous process, but sometimes it helps us humans to think of stages.
(Emily) Okay, so Stage One is the first 5 to 10 years of a dead tree's life.
So if it's got the needles or all the fine twigs left, we might classify that as a class one.
Okay.
And it will look kind of naked.
(Emily) Stage Two is the next 5 to 25 years.
And water begins to seep into the bark.
The wood gets soft.
Leaves and twigs are gone.
And to test if it's a one or a two, Mark uses a really sophisticated scientific technique.
Um, it's a kick test, they say.
No, literally, and you can hear different sounds.
It doesn't go "thunk" when it's sound.
This is what we'd call a class-three log, but we also see it's starting to fall apart.
So this has probably been down about 50 or 60 years to get to this stage.
(Emily) Stage Four is the longest, the next 75 to 200 years.
And there's lots of stuff going on.
The log becomes a decomposing Petri dish, plants, and fungi move in, hundreds of species of  invertebrates take up shop-- insects, mites, slugs,  snails-- tiny mammals burrow in,  salamanders.
Oh, my God, salamanders, they're the tigers  of the undergrowth.
They come in around,  they're hunting everything.
And of course,  all of this stuff is pooping and that becomes part of  the nutrient recycling chain.
I mean, you guys know, I love a good poop story.
But anyway, so finally, there's Stage Five, which is sometimes 400 to 500 years after the tree's initial death.
Five hundred years?
I mean, that's-- this is wild.
It's like when the Mona Lisa was being painted, a tree fell down and now it's still in Stage Four.
I mean, the reality is like, I've been wanting to film at this place for so long.
Like,  just because of this fact.
Like, I found out  that there are people doing a 200-year-long  research study and I was like, "Have I lost my mind?"
I didn't even know that was possible.
Like, and then they're out there like, "No, we actually--it should've been a thousand years, but we are gonna just cash it in early."
It's so nice.
I feel like it's hugging me back.
I'm gonna get ants on my face.
This is how you get termites in your pants.
Is that it?
Is that-- This was a Douglas fir at one time, and now it's a bunch of-- well, actually, that's a scientific term for it, "red mush."
That's what we call it.
Really?
Yeah, and it's very ideal for roots.
Reason we see all these roots is because it holds a lot of water.
So it's kind of like a compost in that way.
It also is releasing a fair amount of its nitrogen at this stage.
After this, it's just returned to the Earth.
Pretty much.
(Emily)  So over the course of maybe  five centuries, a dead tree continues  to give back to its forest-- nutrients, shelter, water, microhabitats for untold numbers of lifeforms.
All of its elements  are cycling back through the system.
Even after being burned  or killed in severe wildfires, forests continue to hold on  to their stored carbon for decades, unless they're  removed by salvage logging.
But all of this only works if a tree stays where it falls.
So when a tree falls in a forest, leave it alone.
Even though it's dead, it's still doing really, really important work.
We can all hope to have such an impact after our own life.
Just dump me out somewhere on the side of the highway.
Okay.
Just let--just let me, you know, feed a possum or something.
I'd be so happy.
After all of that talk  of death and stuff, I wanted to go meet some of these little critters  for myself.
So this is a really exciting find down here.
You know, we talk a lot about  microorganisms in the forest and here's a giant of the invertebrate world.
Although it doesn't seem that big.
This is a millipede.
A species of cherry millipede, and what's  really cool about them is you see these lines  of red alongside the body.
And that's this organism's  warning colors saying, "You know, you don't want to eat me.
I taste really bad."
Emily, um, why do they taste bad?
Cyanide.
Yikes.
How did you find that out?
Oh, the hard way.
Ah, just kidding.
It's a known defense mechanism.
Oh.
These are one of the big cows of the undergrowth.
This is a banana slug, and I hope you can get a sense of scale, but it's, you know, 5 or 6 inches long.
Making some  pretty solid progress on eating some  of this plant material.
So these are just really cool organisms moving at the speed of a slug.
Detritivores like millipedes  and slugs might look tiny, but they've got a huge impact here as nutrient cyclers, turning dead plant and  animal material into energy that can be used by so many  other living things, including more trees.
These log jams, although they look a little unsightly and you know, your instinct  might be to move them out of the way, they actually create habitat  and leach nutrients into the water that can support so many other aquatic invertebrates and vertebrates too.
A temperate rainforest  like this can support an amazing amount of life from the top of the tree down to the ground.
But there's one other area that we haven't quite explored yet.
This is hilarious.
Whoa.
Oh, I feel like I'm being born again.
That's really cold!
Even here underwater  in creeks and in ponds, that slow cycle of  decomposition is still at play.
There're snails and caddisflies, the browsers and the grazers, predators, like the crayfish  and the salamanders.
Everything that gets washed  into these streams will eventually get drawn back up through the roots of trees,  through the soils and the bodies  of the plants and animals.
It's a process  that's been millions of years in the making, and hopefully will be  repeating for millions more.
This is just amazing.
I mean, you stick your head in and you see this entire environment, a whole ecosystem of animals that are calling this place home.
It's all kind of happening  here under the water.
And you know, with just  a mask and some time you can--you can see all of it.
I've never really thought of nature this way.
You know, just nutrients moving around and atoms.
It's such a cool way to see the world.
(Joe)  I know, like,  an experimental forest is such a cool place and I love  that these processes that are happening there, you know, we're also seeing them  in places like the Serengeti, a place that couldn't seem  more different on the surface.
(Emily) Yeah, I mean, all of this decay and nutrient cycling, sometimes it's happening at scales big and small, sometimes very fast and sometimes at a snail's or a slug's pace.
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