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  • For the past 12 weeks, we've been investigating our living planet

  • together and learning how it works on many levels,

  • how populations of organisms interact, how communities thrive

  • and ecosystems change, and how humans are wrecking the nice,

  • perfectly functioning systems Earth has been using

  • for hundreds of thousands of years.

  • And now it's graduation day!

  • This here is like the commencement speech,

  • where I talk to you about the future and our role in it,

  • and how what we're doing to the planet is totally awful,

  • but we're taking steps to undo some of the damage that we've done.

  • So what better way to wrap up our series on ecology than by taking

  • a look at the growing fields of conservation biology

  • and restoration ecology.

  • These disciplines use all the kung fu moves that we've learned

  • about in the past 11 weeks and apply them to

  • protecting ecosystems and cleaning up messes that we've already made.

  • And one of the main things they teach us is that doing these things

  • is difficult, like, in the way that uncooking bacon is difficult.

  • So let's look at what we're doing, and try to uncook this

  • unbelievably large pile of bacon we've made!

  • Just outside of Missoula, Montana, where I live,

  • we've got a Superfund site. Not Superfun...Superfund.

  • A hazardous waste site that

  • the government is in charge of cleaning up.

  • The mess here was made more than a hundred years ago, when there was

  • a dam in the Clark Fork River behind me called the Milltown Dam.

  • This part of Montana has a long history of copper mining,

  • and back in 1908, there was a humongous flood that washed

  • about 4.5 million cubic meters of mine tailings chock full of arsenic

  • and toxic heavy metals into the Clark Fork River.

  • And most of it washed into the reservoir

  • created by the Milltown dam.

  • I mean, actually it was lucky that the dam was there,

  • it had only been completed six months before,

  • or the whole river system, all the way to the Pacific Ocean,

  • would have been a toxic mess.

  • As it happened, though, only about 160 kilometers of the river

  • was all toxic-messed-up.

  • A lot of it recuperated over time, but all that nasty

  • hazardous waste was still sitting behind Milltown Dam,

  • and some of it leached into the groundwater

  • that started polluting nearby resident's wells.

  • So scientists spent decades studying the extent

  • of the damage caused by the waste and coming up with ways to fix it.

  • And from 2006 to 2010, engineers carefully removed

  • all the toxic sediment as well as the dam itself.

  • Now, this stretch of the Clark Fork River runs unimpeded

  • for the first time in over a century, and the restored area

  • where the dam used to be is being turned into a state park.

  • Efforts like this show us conservation biology

  • and restoration ecology in action.

  • Conservation biology involves measuring the biodiversity

  • of an ecosystem and determining how to protect it.

  • In this case, it was used to size up the health

  • of fish populations in the Clark Fork River,

  • which were severely affected by the waste behind the dam,

  • and the dam blocking their access to spawning grounds upstream,

  • and figuring out how to protect them during the dams removal.

  • Restoration ecology, meanwhile, is the science of restoring

  • broken ecosystems, like taking an interrupted, polluted river

  • and turning it into what you see taking shape here.

  • These do-gooder, fix-it-up sciences are practical rather

  • than theoretical, by which I mean, in order to fix something

  • that's broken, you've got to have a good idea of what's

  • making it work to begin with.

  • If something was wrong with the expansion of the Universe,

  • we wouldn't be able to fix it because we have no idea, at all,

  • what's making all that happen.

  • So in order to fix a failing ecosystem, you have to figure out

  • what was holding it together in the first place.

  • And the glue that holds every ecosystem together is biodiversity.

  • But then of course, biodiversity can mean many different things.

  • So far we've generally used it to mean species diversity,

  • or the variety of species in an ecosystem.

  • But there are also other ways of thinking about biodiversity

  • that help conservation biologists and restoration ecologists

  • figure out how to save species and repair ecosystems.

  • In addition to the diversity of species, ecologists look at

  • genetic diversity within a species as a whole and between populations.

  • Genetic diversity is important because it makes evolution possible

  • by allowing a species to adapt to new situations

  • like disease and climate change.

  • And then another level of biodiversity has to do with

  • ecosystem diversity, or the variety of different ecosystems

  • within an area.

  • A big ol' forest, for example, can host several kinds of ecosystems,

  • like wetland, alpine, and aquatic ones.

  • Just like we talked about when we covered ecological succession,

  • the more little pockets you've got performing different functions,

  • the more resilient the region will be as a whole.

  • So, yeah, understanding all of this is really important

  • to figuring out how to repair an ecosystem that is in shambles.

  • But how do conservation biologists take the information about what

  • makes an ecosystem tick and use it to save the place from going under?

  • Well, there's more than one way to approach this problem.

  • One way is called small-population conservation.

  • This approach focuses on identifying species and populations

  • that are really small, and tries to help boost their numbers

  • and genetic diversity.

  • Low population and low genetic diversity are kind of the death knell

  • for a species.

  • They actually feed off each other,

  • one problem making the other problem worse,

  • ultimately causing a species to spiral into extinction.

  • See, when a tiny little population suffers from inbreeding

  • or genetic drift, that is, a shift in its overall genetic makeup,

  • this leads to even less diversity, which in turn

  • causes lower reproduction rates and higher mortality rates,

  • which makes the population smaller still.

  • This terrible little dynamic is known

  • by the awesome term extinction vortex.

  • The next step is to figure out

  • how small a population is too small.

  • Ecologists do this by calculating what's called

  • the minimum viable population, which is the smallest size

  • at which a population can survive and sustain itself.

  • To get at this number, you have to know the real

  • breeding population of, say, grizzly bears

  • in Yellowstone National Park, and then you figure out everything

  • you can about a grizzly's life history:

  • how long they live, who gets to breed the most,

  • how often they can have babies, that kind of thing.

  • After all that information is collected, ecologists can run

  • the numbers and figure out that for the grizzlies in Yellowstone,

  • a population of, say hypothetically, 90 bears would have about

  • a 95% chance of surviving for 100 years,

  • but if there were a population of 100 bears,

  • the population would likely be able to survive for 200 years.

  • Something to note: ecology involves a lot of math.

  • So if you're interested in this, that's just the way it is.

  • So, that's the small-population approach to conservation.

  • Another way of preserving biodiversity focuses on populations

  • whose numbers are in decline,

  • no matter how large the original population was.

  • This is known as declining population conservation,

  • and it involves answering a series of related questions that get

  • at the root of what's causing an organism's numbers to nosedive.

  • First, you have to determine whether the population

  • is actually declining.

  • Then, you have to figure out how big the population

  • historically was and what its requirements were.

  • And finally, you have to get at what's causing the decline

  • and figure out how to address it.

  • Milltown Dam actually gives us a good example of this process.

  • In the winter of 1996, authorities had to release some of the water

  • behind the dam as an emergency measure, because of a big ice flow

  • in the river that was threatening to break the dam.

  • But when they released the water, a bunch of toxic sediment

  • went with it, which raised the copper concentrations downriver

  • to almost 43 times what state standards allowed.

  • As a result, it's estimated about half of the fish downstream died.

  • Half the fish! Dead!

  • And researchers have been monitoring the decline in populations ever since.

  • This information was really helpful in determining what

  • to do with the dam.

  • Because we knew what the fish population was like before

  • and after the release of the sediment, it was decided that

  • it would be best to get the dam out as soon as possible,

  • rather than risk another 1996 scenario.

  • Which brings me to the place where conservation biology

  • and restoration ecology intersect.

  • Restoration ecology is kind of where the rubber meets the road

  • in conservation biology.

  • It comes up with possible solutions for ecological problems.

  • Now, short of a time machine, which I'm working on, you can't

  • really get a natural environment exactly the way it used to be.

  • But you can at least get rid of whatever is causing the problem

  • and help re-create some of the elements that

  • the ecosystem needs to function properly.

  • All this involves a whole suite of strategies.

  • For instance, what's happening in Milltown is an example of

  • structural restoration, basically the removal and cleanup

  • of whatever human impact was causing the problem.

  • In this case, the dam and the toxic sediments behind it.

  • And then the rebuilding of the historical natural structure,

  • here the meanders of the river channel and the vegetation.

  • Another strategy is bioremediation,

  • which recruits organisms temporarily to help remove toxins,

  • like bacteria that eat wastes or plants that

  • leach out metals from tainted soils.

  • Some kinds of fungi and bacteria are even being explored

  • as ways to bio-remediate oil spills.

  • Yet another, somewhat more invasive restoration method

  • is biological augmentation.

  • Rather than removing harmful substances, this involves adding

  • organisms to the ecosystem to restore materials that are gone.

  • Plants that help fix nitrogen like beans, acacia trees

  • and lupine are often used to replenish nitrogen in soils

  • that have been damaged by things like mining or overfarming.

  • And ecologists sometimes add mycorrhizal fungi to help

  • new plantings like native grass take hold.

  • But of course, we're just humans, and we're not as smart

  • as millions of years of evolution.

  • Sometimes we get things wrong.

  • For example, when you bring an

  • invasive species into a place

  • to eradicate an invasive species, sometimes you just end up with

  • two invasive species on your hands,

  • which collapses the ecosystem even more rapidly.

  • The introduction of cane toads to Australia in the 1930s

  • to control beetles is a particularly infamous example.

  • Not only are they everywhere now but because they're toxic they're

  • poisoning native species like dingos that try to eat them. Nice.

  • So you know what? I have an idea.

  • After spending the past couple of weeks talking about

  • ecological problems, I've come to the conclusion that it's just

  • easier to protect ecosystems rather than trying to fix them.

  • Because we know a lot about what makes ecosystems tick,

  • so if we spend more time trying to save them from us and our stuff,

  • we'll spend less time cleaning up after ourselves

  • and running the risks of getting it wrong.

  • Because as we all know, the sad fact is:

  • uncooking bacon is impossible. But we can eat it.

  • Thank you for joining me on this quick three-month jaunt

  • through the natural world,

  • I hope it made you smarter not just in terms of passing your exams

  • but also in terms of being a Homo-sapien

  • that inhabits this planet more wisely.

  • And thank you to everyone who helped us put these episodes together:

  • our technical director Nick Jenkins,

  • our editor Caitlin Hoffmeister,

  • our writers Blake DePastino, Jesslyn Shields and myself,

  • our sound designer Michael Aranda,

  • and our animators and designers Peter Winkler and Amber Bushnell.

  • And the good news is: there's more Crash Course coming at you soon.

  • If you have any questions or comments or ideas, we're on Facebook

  • and Twitter, and of course, down in the comments below.

  • We'll see you next time.

For the past 12 weeks, we've been investigating our living planet

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保全と修復の生態学。クラッシュコース エコロジー#12 (Conservation and Restoration Ecology: Crash Course Ecology #12)

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    Chi-feng Liu に公開 2021 年 01 月 14 日
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