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There’s only one place you tend to get mountains: 00:00
where two tectonic plates meet. 00:02
Essentially, 00:04
two plates smash together 00:05
and push rock up 00:06
to form a line of mountains along the boundary. 00:07
And sure, there’s more to it, 00:10
but that’s basically the story. 00:11
Which makes it really irritating 00:13
that there’s a mountain range in the wrong place. 00:14
North America’s Rocky Mountains 00:17
are located smack in the middle of the continent, 00:18
hundreds of kilometers 00:21
away from the nearest plate boundary 00:22
at the edge of the Pacific Ocean. 00:24
And it turns out the question of 00:26
why the Rocky Mountains formed where they did 00:27
is actually a pretty hot debate between geologists. 00:30
So let's take a look at what we know, 00:33
and what’s still a mystery, 00:35
about why one of the world’s 00:36
most iconic mountain ranges is where it is. 00:36
[intro ♪] 00:40
The Rocky Mountains we see today started ascending 00:44
around 125 million years ago during the Sevier Orogeny. 00:47
An orogeny is just what geologists call a mountain building event. 00:50
The Sevier Orogeny stretched 00:55
all the way from present-day Alaska to Mexico. 00:56
It folded and fractured layers of sedimentary rocks, 00:59
bunching them up on themselves 01:03
to start building mountains. 01:04
But it wasn’t the only game in town. 01:06
The subject of the most debate 01:08
is the Laramide Orogeny, 01:09
which was largely responsible 01:11
for the range in the United States. 01:12
Instead of folding layers of sediment, 01:14
these mountains were built by breaking 01:16
and piling up hard rock like granite. 01:18
This mainly occurred a little later, 01:20
between 80 and 55 million years ago. 01:22
Back then the seafloor of the eastern Pacific 01:24
was made up of two oceanic plates, 01:27
and both were subducting beneath North America. 01:29
Sliding under the continental plate and into the mantle. 01:32
On the other side of the continent, the Atlantic Ocean 01:35
was in the process of opening, 01:37
so that oceanic plate was pushing North America 01:39
towards the west. 01:42
Despite the Rockies being up to 1500 kilometers 01:43
from the Pacific plate boundary, 01:46
geologists do agree that this subduction zone 01:48
is responsible for building the mountains. 01:51
What they argue over is how 01:53
it could have happened so darn far from the coast. 01:54
But they’ve come up with four hypotheses. 01:57
The first is retroarc thrusting. 01:59
The idea that the North American plate 02:02
was pushing so hard to the west 02:04
that instead of the oceanic plate slipping smoothly 02:06
beneath the continent, 02:09
it got stuck.* 02:10
And all that stress caused 02:11
the continent to crumple like a car wreck. 02:12
But this begs the question of what did the pushing. 02:14
One idea is that it could have been the seafloor spreading 02:17
from the Atlantic Ocean on the other side of the continent. 02:19
But when we look at rates of spreading recorded in the Atlantic seafloor, 02:22
we don’t see much evidence for it being in such a hurry. 02:26
And regardless of where the push came from, 02:29
for this idea to work, 02:31
the section of North America west of the Rockies 02:32
would need to be strong enough 02:35
to withstand the collision 02:36
and pass the stress inland. 02:38
Which, it’s not, at least it doesn’t seem like it. 02:39
There are faults out west – 02:43
meaning cracks where the crust is weak. 02:44
A bunch of these are older than the Rockies, 02:46
so why wouldn’t the crumpling have happened there? 02:48
So the second idea is orogenic float. 02:51
Maybe those faults we mentioned 02:54
detached a section of the lower crust 02:55
from the rest of the continent. 02:57
Then it could float, essentially unattached. 02:59
Then the force of the Pacific seafloor subducting 03:01
could skip this section 03:04
and get passed inland to the east. 03:05
But then, 03:07
But in that case, where is this detached section of crust? 03:08
It would have eventually smashed against the Rockies, 03:11
and we don’t see any evidence 03:13
of that happening at the right time. 03:15
So the third is a transpressional collision. 03:17
Transpression is just a combination of the words transform and compression. 03:20
It means a fault that is both moving side to side 03:24
and together at the same time. 03:27
This idea is that a long 03:29
north-south transpressional fault existed 03:30
where the Rockies are today. 03:32
North America was essentially split in two, 03:34
the main continent to the east and a thin “ribbon” continent to the west. 03:37
The magnetic signature in some of the rocks 03:41
near the Canadian Rockies indicate 03:43
they formed thousands of kilometers to the south. 03:44
So that’s strong evidence for this idea. 03:47
The transform part of the fault 03:50
would have moved the ribbon continent northwards, 03:51
including those rocks. 03:53
And the compression part would have pushed it 03:55
up and over the main North American plate 03:57
to build the mountains. 03:59
The only catch is if a ribbon continent 04:00
collided with the rest of North America, 04:02
geologists expect at one point there 04:04
would have been an ocean between the two. 04:06
And we just don’t see the kind of volcanic evidence that would be left over 04:08
from an oceanic plate subducting before this collision. 04:11
See, oceanic plates have a ton of water in them, 04:14
which gets released under heat and pressure. 04:17
Water lowers the melting point 04:19
of the surrounding rocks and creates magma. 04:20
This means a subducting plate tends to create volcanoes. 04:23
In this case they could actually end up 04:26
east of the Rockies, in what we call… 04:28
The Great Plains. 04:30
Which we call that because of a notable lack of volcanoes 04:32
and other volcano-shaped objects. 04:35
So. 04:37
This is also relevant for the final idea, flat-slab subduction. 04:38
While there is still a lot of debate, 04:42
this is the most popular of the four. 04:44
Normally, subducting plates 04:46
plunge into the mantle at a steep angle, 04:47
which means they quickly get deep enough 04:49
to release their water and form magma. 04:51
But if an oceanic plate was younger and hotter, 04:54
it could be more buoyant and not sink as easily. 04:56
So the idea here is that the subducting plate 04:59
slid along underneath North America 05:01
for over 700 kilometers 05:03
before finally getting deep enough to produce magma. 05:05
That melted rock would go on 05:08
to make up the core of the Rockies, 05:10
just much further inland than expected. 05:11
What’s more, scraping one plate 05:14
under another for that long would have transferred stress 05:16
to the same area – 05:18
again with the crumpling. 05:20
But even though this is 05:21
the most popular hypothesis, 05:22
it still has a problem of its own. 05:24
There are remnants of ancient volcanoes to the west of the Rockies in both Canada and 05:26
Mexico, so… it seems like that’s where the subducting plate was producing magma. 05:31
Not where this hypothesis would expect. 05:36
So the truth is, 05:38
we don’t know the definitive answer here yet 05:39
and none of these models 05:41
have been able to fully explain every line of evidence. 05:42
Some studies conclude 05:45
that we need a combination 05:46
of these different mechanisms 05:47
to explain what happened. 05:49
For example, it could be that one hypothesis was responsible 05:50
for the first mountains built and another took over later. 05:53
Or it could be that different mechanisms 05:56
were at play in different sections of the mountain range 05:58
we see today. 06:00
For example, 06:01
Some researchers have suggested that a “corridor” of flat slab subduction 06:02
could have been responsible for the mountains in the central United States. 06:05
It just doesn’t explain 06:09
the mountains to the north and south. 06:10
What is clear is the Earth 06:12
doesn’t always do what we expect it to, 06:13
and reconstructing the events 06:15
that created what we see today can be pretty challenging. 06:16
But at least, it does make for some great good skiing though! 06:19
If you enjoyed this episode, 06:22
you are probably the kind of person 06:23
who likes rocks. 06:24
Well, rock enjoyers, 06:25
And so to all the rock enjoyers out there, 06:26
I have a thought for you to ponder. 06:28
What Imagine if an incredibly cool rock 06:29
showed up at your door? 06:31
And what if that happened again the next month, 06:33
and the one after that? 06:36
Well I don’t want to say too much 06:37
so I’ll leave you with that, 06:38
lovers of shiny things… 06:39
and say to I’ll tell you, 06:40
you should look out for our live premiere on October 2nd. 06:41
Until then, thanks for watching. 06:44
[ ♪ OUTRO ] 06:46

– English Lyrics

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Lyrics & Translation

[English]
There’s only one place you tend to get mountains:
where two tectonic plates meet.
Essentially,
two plates smash together
and push rock up
to form a line of mountains along the boundary.
And sure, there’s more to it,
but that’s basically the story.
Which makes it really irritating
that there’s a mountain range in the wrong place.
North America’s Rocky Mountains
are located smack in the middle of the continent,
hundreds of kilometers
away from the nearest plate boundary
at the edge of the Pacific Ocean.
And it turns out the question of
why the Rocky Mountains formed where they did
is actually a pretty hot debate between geologists.
So let's take a look at what we know,
and what’s still a mystery,
about why one of the world’s
most iconic mountain ranges is where it is.
[intro ♪]
The Rocky Mountains we see today started ascending
around 125 million years ago during the Sevier Orogeny.
An orogeny is just what geologists call a mountain building event.
The Sevier Orogeny stretched
all the way from present-day Alaska to Mexico.
It folded and fractured layers of sedimentary rocks,
bunching them up on themselves
to start building mountains.
But it wasn’t the only game in town.
The subject of the most debate
is the Laramide Orogeny,
which was largely responsible
for the range in the United States.
Instead of folding layers of sediment,
these mountains were built by breaking
and piling up hard rock like granite.
This mainly occurred a little later,
between 80 and 55 million years ago.
Back then the seafloor of the eastern Pacific
was made up of two oceanic plates,
and both were subducting beneath North America.
Sliding under the continental plate and into the mantle.
On the other side of the continent, the Atlantic Ocean
was in the process of opening,
so that oceanic plate was pushing North America
towards the west.
Despite the Rockies being up to 1500 kilometers
from the Pacific plate boundary,
geologists do agree that this subduction zone
is responsible for building the mountains.
What they argue over is how
it could have happened so darn far from the coast.
But they’ve come up with four hypotheses.
The first is retroarc thrusting.
The idea that the North American plate
was pushing so hard to the west
that instead of the oceanic plate slipping smoothly
beneath the continent,
it got stuck.*
And all that stress caused
the continent to crumple like a car wreck.
But this begs the question of what did the pushing.
One idea is that it could have been the seafloor spreading
from the Atlantic Ocean on the other side of the continent.
But when we look at rates of spreading recorded in the Atlantic seafloor,
we don’t see much evidence for it being in such a hurry.
And regardless of where the push came from,
for this idea to work,
the section of North America west of the Rockies
would need to be strong enough
to withstand the collision
and pass the stress inland.
Which, it’s not, at least it doesn’t seem like it.
There are faults out west –
meaning cracks where the crust is weak.
A bunch of these are older than the Rockies,
so why wouldn’t the crumpling have happened there?
So the second idea is orogenic float.
Maybe those faults we mentioned
detached a section of the lower crust
from the rest of the continent.
Then it could float, essentially unattached.
Then the force of the Pacific seafloor subducting
could skip this section
and get passed inland to the east.
But then,
But in that case, where is this detached section of crust?
It would have eventually smashed against the Rockies,
and we don’t see any evidence
of that happening at the right time.
So the third is a transpressional collision.
Transpression is just a combination of the words transform and compression.
It means a fault that is both moving side to side
and together at the same time.
This idea is that a long
north-south transpressional fault existed
where the Rockies are today.
North America was essentially split in two,
the main continent to the east and a thin “ribbon” continent to the west.
The magnetic signature in some of the rocks
near the Canadian Rockies indicate
they formed thousands of kilometers to the south.
So that’s strong evidence for this idea.
The transform part of the fault
would have moved the ribbon continent northwards,
including those rocks.
And the compression part would have pushed it
up and over the main North American plate
to build the mountains.
The only catch is if a ribbon continent
collided with the rest of North America,
geologists expect at one point there
would have been an ocean between the two.
And we just don’t see the kind of volcanic evidence that would be left over
from an oceanic plate subducting before this collision.
See, oceanic plates have a ton of water in them,
which gets released under heat and pressure.
Water lowers the melting point
of the surrounding rocks and creates magma.
This means a subducting plate tends to create volcanoes.
In this case they could actually end up
east of the Rockies, in what we call…
The Great Plains.
Which we call that because of a notable lack of volcanoes
and other volcano-shaped objects.
So.
This is also relevant for the final idea, flat-slab subduction.
While there is still a lot of debate,
this is the most popular of the four.
Normally, subducting plates
plunge into the mantle at a steep angle,
which means they quickly get deep enough
to release their water and form magma.
But if an oceanic plate was younger and hotter,
it could be more buoyant and not sink as easily.
So the idea here is that the subducting plate
slid along underneath North America
for over 700 kilometers
before finally getting deep enough to produce magma.
That melted rock would go on
to make up the core of the Rockies,
just much further inland than expected.
What’s more, scraping one plate
under another for that long would have transferred stress
to the same area –
again with the crumpling.
But even though this is
the most popular hypothesis,
it still has a problem of its own.
There are remnants of ancient volcanoes to the west of the Rockies in both Canada and
Mexico, so… it seems like that’s where the subducting plate was producing magma.
Not where this hypothesis would expect.
So the truth is,
we don’t know the definitive answer here yet
and none of these models
have been able to fully explain every line of evidence.
Some studies conclude
that we need a combination
of these different mechanisms
to explain what happened.
For example, it could be that one hypothesis was responsible
for the first mountains built and another took over later.
Or it could be that different mechanisms
were at play in different sections of the mountain range
we see today.
For example,
Some researchers have suggested that a “corridor” of flat slab subduction
could have been responsible for the mountains in the central United States.
It just doesn’t explain
the mountains to the north and south.
What is clear is the Earth
doesn’t always do what we expect it to,
and reconstructing the events
that created what we see today can be pretty challenging.
But at least, it does make for some great good skiing though!
If you enjoyed this episode,
you are probably the kind of person
who likes rocks.
Well, rock enjoyers,
And so to all the rock enjoyers out there,
I have a thought for you to ponder.
What Imagine if an incredibly cool rock
showed up at your door?
And what if that happened again the next month,
and the one after that?
Well I don’t want to say too much
so I’ll leave you with that,
lovers of shiny things…
and say to I’ll tell you,
you should look out for our live premiere on October 2nd.
Until then, thanks for watching.
[ ♪ OUTRO ]

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