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It`s Okay To Be Smart, The Crime Wave We Can Blame on… Neutron Stars? (1)

The Crime Wave We Can Blame on… Neutron Stars? (1)

There's a crime wave sweeping the world right now.

- [Newsreader] The troubling trend

targeting a key car component.

- [Newsreader 2] Thieves targeting cars

for their catalytic converters.

- These thefts that take just minutes to carry out.

- And a thief can remove one from your car

in 60 seconds or less.

- You feel violated.

- [Joe] The thieves are on the hunt for something

that fetches big bucks on the black market.

- [Newsreader 3] A nearly $7 million theft ring.

- [Newsreader 4] They want the valuable metals

inside the converters.

- [Interviewee] This would be a very quick way

for them to make a quick buck.

- [Joe] Numbers are absolutely skyrocketing

and public officials are scrambling for answers.

- We're trending in the wrong direction.

- And people are getting tired of it.

- This is a growing problem, there's no excuse for it.

- Turns out we can blame it all on this:

(stars whirring)

(curious music)

Hey smart people, Joe here.

So back in the '70s, air pollution was out of control.

Many U.S. cities were completely blanketed in smog

and people were getting sick,

all these warnings about acid rain,

and one of the big culprits was car exhaust.

So the U.S. passed these huge, new environmental laws

like the Clean Air Act,

which led to one of the most monumental innovations ever

in cleaning up the way that we drive:

the catalytic converter.

A catalytic converter is basically

an extra little chamber along your car's exhaust pipe,

EV owners, this doesn't apply to you.

This magical little box

takes dangerous chemicals and engine exhaust

and transforms them into relatively harmless gases

that are better for the environment and public health.

I mean, car exhaust still causes global warming

but at least this solved that whole smog thing.

But in recent years, catalytic converters

have become one of the most stolen items on cars.

Thefts have risen almost 4000% since 2018

(burglar cackles)

and numbers are still on the rise

and that's all because of what's inside.

That little thing on your exhaust

that you've probably never looked at,

is a literal treasure chest full of valuable metals,

platinum, palladium and this one, rhodium,

the most expensive metal on planet earth.

But why do we need this crazy-expensive metal

in something that cleans literally

the dirtiest stuff that comes outta your car?

Well, because of the very unique chemistry

that happens inside of a catalytic converter.

Rhodium belongs to a family of metals

that are extremely resistant

to oxidation and corrosion and heat.

So it can stand up

to conditions inside your car's exhaust system

and all of the junk that comes through it,

but it also has another super important property:

it's a catalyst,

which means it can speed up certain chemical reactions.

Here's an example:

burning gasoline creates harmful chemicals

like nitrogen oxides, which can damage the ozone layer,

contribute to acid rain, and warm up our planet.

But the rhodium in a catalytic converter

turns it into harmless nitrogen and oxygen gas

and it can do this over and over and over again,

as long as nobody saws it off your car

in the middle of the night.

A catalytic converter

has something like a couple of grams of rhodium in it,

which has a street value of almost $1,000.

To put this in perspective,

right now, a one kilogram bar of gold

is worth around $57,000.

That's a lot of money, but that same amount of rhodium

would be worth more than half a million dollars.

Here's a little periodic table I have

that has actual samples

of all of the non-dangerous, non-deadly elements.

This little microscopic piece of rhodium I have in here,

hold on, we're gonna need to enhance.

Let's move... Grab the macro lens or something.

So this tiny little piece is worth almost $10.

So why is this stuff so expensive?

When we look at rhodium

and it's neighbors on the periodic table

we find a lot of stuff that's ridiculously rare,

at least in Earth's crust where we can get to it easily.

If we represent the total

of all the elements in Earth's crust

by a roll of toilet paper stretching from here to London,

rhodium would make up just this much.

To figure out why these precious metals are so rare,

we have to talk about how elements are made.

And to understand how elements are made

and where they come from,

we have to spend a little bit of time with this.

Every box on the periodic table represents one element.

And the type of element you are

is determined by the number of protons you have.

If you're an atom with just one proton,

you're hydrogen, here at the upper-left corner.

If we add a proton, we have element two, helium, instead.

Six protons, carbon.

Eight, you're oxygen, and so on.

Protons are positively charged,

but like charges repel each other

like identical ends of a magnet.

So why doesn't that repulsion make a nucleus fall apart?

Well, because there's another fundamental force

at play inside a nucleus, the nuclear force.

You can think of the nuclear force as Velcro

that only works when protons or neutrons

are pushed very close together.

See, atoms contain both protons and neutrons.

Neutrons also have this sticky nuclear force Velcro,

but unlike protons they're uncharged,

they don't repel other stuff.

So neutrons act like an atomic glue

that can help hold a nucleus together.

Adding or subtracting neutrons can change an atoms mass

but not what type of element it is.

It's only when we add or take away a proton

along with enough neutrons

to keep a nucleus from falling apart

that we make a new chemical element.

And to get protons and neutrons close enough together

for that nuclear Velcro to do its thing

requires a lot of heat and energy.

Amounts that we only find in special places

and at special times.

The hot, dense universe that existed just after the Big Bang

created the perfect conditions

to squish protons and neutrons together.

That's how the lightest,

most abundant elements on the periodic table were created.

Stuff like hydrogen and helium.

In fact, all of the hydrogen that exists in the universe

was created in those first few minutes after the Big Bang.

But to create heavier and heavier nuclei,

you need more and more energy.

Unfortunately, the Big Bang only happened once,

13.8 billion years ago.

And all of its energy has been spreading out

as the universe continues to expand.

So where else can we find enough energy

to squish nuclei together?

The fusion reactions that make stars burn

turn lighter elements into heavier ones

by smashing nuclei together.

Two atoms of hydrogen make one atom of helium,

smash three helium nuclei together, you get carbon,

add one more helium nucleus, you get oxygen,

you get the idea.

But cooking up these different elements gets harder

as we move down and across the periodic table.

If a nucleus gets big enough, even the immense pressures

and energies inside the core of a star

aren't enough to keep sticking on new protons.

It turns out that iron is the heaviest element

that can be made in a star.

So what about the rest of the periodic table?

Well, everything after uranium was made by humans

but we still need a way to make all of these.

Luckily, there is one more way to add protons to a nucleus:

by adding neutrons.

Because neutrons don't have a charge,

it takes less energy to get them to stick to a nucleus

but adding neutrons can also make a nucleus unstable.

That's why radioactive isotopes spontaneously decay

and eject subatomic particles and radiation in the process.

Sometimes a neutron that's been captured by a nucleus

can decay into a proton.

And since that's one more proton that wasn't there before

we've created a new element.

If that seems weird and confusing,

well, welcome to physics.

This way of adding protons to a nucleus

by actually adding neutrons

is how most elements on the periodic table are born.

But in this story,

every answer seems to bring us to one more problem.

Where do you go to find big piles of neutrons

just waiting to get smashed onto nuclei?

Before I answer that,

first I wanna take a quick moment to thank our patrons,

because while we're on the subject of making new things,

your support helps us make these videos.

We can't thank you enough.

And if you wanna join our community of supporters,

just check out the link down in description.

I also wanna let you know

that another great way to support the show for free

is by watching new episodes when they're first released.

This helps spread the show

to other subscribers and to new viewers.

If you are already part of the early squad, thank you.

And if not, hit the bell icon next to the subscribe button,

our whole community of curious learners will thank you.

So where do you go to find big piles of neutrons

waiting to get smashed onto nuclei?

Well, one place is dying low-mass stars.

The ones that don't go out in those violent explosions

like their more massive cousins.

They've got lots of free neutrons floating around

so every so often a nucleus can grab one,

it decays into a proton

and becomes a slightly heavier element.

That new element can grab neutron after neutron,

some occasionally decaying into protons along the way,

forming heavier and heavier elements.

This is a slow process

that basically walks box by box along the periodic table.

But it takes billions of years for these stars to die

so it's not like they've got anything better to do.

But there's another way to add a bunch of neutrons at once.

And one place that we find it is in a supernova,

the explosive end of a massive dying star,

which is full of free neutrons

and a whole bunch of stellar junk.

In the immense energy of a supernova explosion,

lots of neutrons can be slapped onto a nucleus at once

before they have time to decay.

Then when that decay finally does happen,

you've effectively added

a whole bunch of protons all at once.

So instead of tiny steps,

we can take big leaps across the periodic table

and end up with really heavy elements, super quick.

We used to think a supernova was the only place

that this rapid neutron capture could happen.

Today, we know that's not true.

After they collapse and go boom, exploding stars

often leave unthinkably dense neutron stars in their wake.

Unsurprisingly, neutron stars are full of neutrons

and if two neutron stars come close enough together,

spiral together and merge,

they release tidal waves of these free neutrons.

Exactly the ingredients

to take those big leaps across the periodic table.

Creating new elements and merging neutron stars

used to be purely theoretical,

but in recent years

we've actually witnessed these collisions

and felt their gravitational aftershocks.

The light given off by one merger

900 million light-years away confirmed

that heavy elements like gold

do form during these violent events.

Sometimes enough to make 10 Earth's worth of gold

in a single merger.

Is this same process true for rhodium too?

Well, we don't really know, but scientists think

that it's likely colliding neutron stars could,

in fact, be where most of the heavy metal end

of the periodic table is born.

But there's still much about these processes

that scientists don't fully understand.

Rhodium and some of its rare neighbors,

they likely form in other ways too,

perhaps somewhere in between these rapid and slow processes.

But even in a universe

that's experienced several generations of dying stars

across nearly 14 billion years of existence,

these explosive atomic nurseries are rare

and pretty spread out.

Across the universe, elements made in these processes

are about a million times more scarce

The Crime Wave We Can Blame on… Neutron Stars? (1) Die Verbrechenswelle, die wir auf... Neutronensterne schieben können? (1) La ola de crímenes que podemos achacar a... ¿las estrellas de neutrones? (1) De misdaadgolf die we kunnen wijten aan... neutronensterren? (1)

There's a crime wave sweeping the world right now. ||||охоплює||||

- [Newsreader] The troubling trend Newsreader|||

targeting a key car component.

- [Newsreader 2] Thieves targeting cars |Thieves||

for their catalytic converters. ||catalytic|converters

- These thefts that take just minutes to carry out. |thefts|||||||

- And a thief can remove one from your car

in 60 seconds or less.

- You feel violated. ||violated

- [Joe] The thieves are on the hunt for something

that fetches big bucks on the black market. |||доларів||||

- [Newsreader 3] A nearly $7 million theft ring.

- [Newsreader 4] They want the valuable metals

inside the converters.

- [Interviewee] This would be a very quick way interviewee|||||||

for them to make a quick buck.

- [Joe] Numbers are absolutely skyrocketing ||||skyrocketing

and public officials are scrambling for answers. ||i funzionari||scrambling||

- We're trending in the wrong direction.

- And people are getting tired of it.

- This is a growing problem, there's no excuse for it.

- Turns out we can blame it all on this: turns||||||||

(stars whirring) |whirring

(curious music)

Hey smart people, Joe here.

So back in the '70s, air pollution was out of control.

Many U.S. cities were completely blanketed in smog ||||||blanketed||smog

and people were getting sick,

all these warnings about acid rain, ||avvertimenti|||

and one of the big culprits was car exhaust. |||||винуватці|||вихлопні гази

So the U.S. passed these huge, new environmental laws

like the Clean Air Act,

which led to one of the most monumental innovations ever

in cleaning up the way that we drive:

the catalytic converter.

A catalytic converter is basically

an extra little chamber along your car's exhaust pipe,

EV owners, this doesn't apply to you. EV owners||||||

This magical little box

takes dangerous chemicals and engine exhaust

and transforms them into relatively harmless gases

that are better for the environment and public health.

I mean, car exhaust still causes global warming

but at least this solved that whole smog thing.

But in recent years, catalytic converters

have become one of the most stolen items on cars.

Thefts have risen almost 4000% since 2018

(burglar cackles) il ladro|

and numbers are still on the rise

and that's all because of what's inside.

That little thing on your exhaust

that you've probably never looked at,

is a literal treasure chest full of valuable metals,

platinum, palladium and this one, rhodium, платина|palladium||||this one rhodium

the most expensive metal on planet earth.

But why do we need this crazy-expensive metal

in something that cleans literally |||cleans = it cleans|

the dirtiest stuff that comes outta your car? |the dirtiest||||виходить з||

Well, because of the very unique chemistry

that happens inside of a catalytic converter.

Rhodium belongs to a family of metals

that are extremely resistant

to oxidation and corrosion and heat. |ossidazione||corrosion||heat

So it can stand up

to conditions inside your car's exhaust system

and all of the junk that comes through it,

but it also has another super important property:

it's a catalyst, ||a catalyst

which means it can speed up certain chemical reactions.

Here's an example:

burning gasoline creates harmful chemicals |gasoline|||

like nitrogen oxides, which can damage the ozone layer, ||оксиди азоту||||||

contribute to acid rain, and warm up our planet.

But the rhodium in a catalytic converter

turns it into harmless nitrogen and oxygen gas

and it can do this over and over and over again,

as long as nobody saws it off your car ||||saws||||

in the middle of the night.

A catalytic converter ||converter

has something like a couple of grams of rhodium in it, has||||||||||

which has a street value of almost $1,000. which||||||

To put this in perspective,

right now, a one kilogram bar of gold |||||||oro

is worth around $57,000.

That's a lot of money, but that same amount of rhodium ||||money||||||

would be worth more than half a million dollars.

Here's a little periodic table I have

that has actual samples |||che ha campioni reali

of all of the non-dangerous, non-deadly elements.

This little microscopic piece of rhodium I have in here,

hold on, we're gonna need to enhance. ||||||покращити

Let's move... Grab the macro lens or something. ||візьми|||||

So this tiny little piece is worth almost $10. Отже|||||||

So why is this stuff so expensive? ||||||дороге

When we look at rhodium коли||||

and it's neighbors on the periodic table і||||||

we find a lot of stuff that's ridiculously rare, ми||||||||

at least in Earth's crust where we can get to it easily. |||Землі||||||||легко доступно

If we represent the total ||||загальний

of all the elements in Earth's crust

by a roll of toilet paper stretching from here to London, за||||||розтягування||||Лондон

rhodium would make up just this much. родій||||||

To figure out why these precious metals are so rare, |||||дорожезні||||

we have to talk about how elements are made. ми||||||||

And to understand how elements are made і||||||створюються

and where they come from, і||||

we have to spend a little bit of time with this. ми||||||||||

Every box on the periodic table represents one element. кожен||||||||

And the type of element you are і||||||

is determined by the number of protons you have. ||||||||маєте

If you're an atom with just one proton,

you're hydrogen, here at the upper-left corner.

If we add a proton, we have element two, helium, instead. ||||протон|||||гелій|замість

Six protons, carbon. ||вуглець

Eight, you're oxygen, and so on.

Protons are positively charged, |||заряджені

but like charges repel each other |||||інші

like identical ends of a magnet. |||||магніт

So why doesn't that repulsion make a nucleus fall apart? |||||зробити||||

Well, because there's another fundamental force ||||фундаментальний|

at play inside a nucleus, the nuclear force. |||||||сила

You can think of the nuclear force as Velcro

that only works when protons or neutrons це||||||

are pushed very close together. ||||разом

See, atoms contain both protons and neutrons. Дивись||||||нейтрони

Neutrons also have this sticky nuclear force Velcro, нейтрони||||липкий|||

but unlike protons they're uncharged, ||||нейтральні

they don't repel other stuff. ||||речі

So neutrons act like an atomic glue ||||||клей

that can help hold a nucleus together. ||||||разом

Adding or subtracting neutrons can change an atoms mass додавання||||||||маса

but not what type of element it is. але|||||||

It's only when we add or take away a proton

along with enough neutrons

to keep a nucleus from falling apart

that we make a new chemical element.

And to get protons and neutrons close enough together

for that nuclear Velcro to do its thing

requires a lot of heat and energy. ||||||енергії

Amounts that we only find in special places Суми|||||||

and at special times. |||рази

The hot, dense universe that existed just after the Big Bang ||щільний||||||||

created the perfect conditions |||умови

to squish protons and neutrons together. |||||разом

That's how the lightest, |||найлегший

most abundant elements on the periodic table were created. ||||||||створені

Stuff like hydrogen and helium. ||||гелій

In fact, all of the hydrogen that exists in the universe ||весь||||||||

was created in those first few minutes after the Big Bang. був||||||||||

But to create heavier and heavier nuclei, Але||||||ядер

you need more and more energy. |||||енергія

Unfortunately, the Big Bang only happened once, |цей|||||

13.8 billion years ago.

And all of its energy has been spreading out і||||||||

as the universe continues to expand. |||||розширюватися

So where else can we find enough energy Отже|||||||

to squish nuclei together? |||разом

The fusion reactions that make stars burn ||||||горіти

turn lighter elements into heavier ones |||||елементи

by smashing nuclei together. |||разом

Two atoms of hydrogen make one atom of helium, ||||||||гелій

smash three helium nuclei together, you get carbon, ||||разом|||вуглець

add one more helium nucleus, you get oxygen, |||||||кисень

you get the idea. |||ідею

But cooking up these different elements gets harder |||||||важче

as we move down and across the periodic table. ||||||||таблиця

If a nucleus gets big enough, even the immense pressures |||||достатньо великий||||

and energies inside the core of a star і|||||||зірка

aren't enough to keep sticking on new protons. не вистачає|||||||

It turns out that iron is the heaviest element воно||||||||елемент

that can be made in a star. ||||||зірка

So what about the rest of the periodic table? Отже||||||||

Well, everything after uranium was made by humans Ну|||уранію||||

but we still need a way to make all of these. але||||||||||ці

Luckily, there is one more way to add protons to a nucleus: На щастя||||||||протони|||ядро

by adding neutrons.

Because neutrons don't have a charge, Бо|||||

it takes less energy to get them to stick to a nucleus ||||||їх||прилипати|||ядро

but adding neutrons can also make a nucleus unstable. але||||||||

That's why radioactive isotopes spontaneously decay Ось чому||радіоактивний|||

and eject subatomic particles and radiation in the process. і||||||||процес

Sometimes a neutron that's been captured by a nucleus ||||||||ядро

can decay into a proton. ||||протон

And since that's one more proton that wasn't there before І|||||протон||||раніше

we've created a new element. ||||елемент

If that seems weird and confusing, |||||заплутаний

well, welcome to physics. |||фізика

This way of adding protons to a nucleus цей спосіб|||||||

by actually adding neutrons |||нейтрони

is how most elements on the periodic table are born. ||||на||періодичний|||народжуються

But in this story, |||але в цій історії

every answer seems to bring us to one more problem. кожна|||||||||

Where do you go to find big piles of neutrons де|||||знайти||||

just waiting to get smashed onto nuclei? ||||||ядра

Before I answer that, Перед|||

first I wanna take a quick moment to thank our patrons, перший||||||||||

because while we're on the subject of making new things,

your support helps us make these videos.

We can't thank you enough.

And if you wanna join our community of supporters,

just check out the link down in description.

I also wanna let you know

that another great way to support the show for free

is by watching new episodes when they're first released.

This helps spread the show

to other subscribers and to new viewers.

If you are already part of the early squad, thank you.

And if not, hit the bell icon next to the subscribe button,

our whole community of curious learners will thank you.

So where do you go to find big piles of neutrons

waiting to get smashed onto nuclei? |||||ядра

Well, one place is dying low-mass stars. Ну|||||||

The ones that don't go out in those violent explosions ті|||||||||вибухи

like their more massive cousins. ||||родичі

They've got lots of free neutrons floating around Вони мають|||||||

so every so often a nucleus can grab one, так||||||||

it decays into a proton |розпадається|||протон

and becomes a slightly heavier element. |||||елемент

That new element can grab neutron after neutron, Цей|||||||

some occasionally decaying into protons along the way, деякі||розпадатися|||||

forming heavier and heavier elements. формування||||

This is a slow process Цей||||

that basically walks box by box along the periodic table. який|||коробка||||||

But it takes billions of years for these stars to die Але||||||||||

so it's not like they've got anything better to do. так||||вони||нічого кращого|||

But there's another way to add a bunch of neutrons at once. Але|||||||||||одразу

And one place that we find it is in a supernova, І||||||||||супернова

the explosive end of a massive dying star, вибуховий|вибуховий кінець||||||

which is full of free neutrons який|||||

and a whole bunch of stellar junk. ||||||сміття

In the immense energy of a supernova explosion, В||||||супернова|

lots of neutrons can be slapped onto a nucleus at once багато|||||прикріплено|на||||

before they have time to decay. перед|||||

Then when that decay finally does happen, тоді||||||

you've effectively added ти||

a whole bunch of protons all at once. |||||||одразу ж

So instead of tiny steps, ||||кроки

we can take big leaps across the periodic table ми||||||||

and end up with really heavy elements, super quick. і||||||||

We used to think a supernova was the only place Ми|||||||||

that this rapid neutron capture could happen. що||||||може статися

Today, we know that's not true. Сьогодні|||||

After they collapse and go boom, exploding stars після того як|||||||

often leave unthinkably dense neutron stars in their wake. ||незбагненно||||||слідах

Unsurprisingly, neutron stars are full of neutrons не дивно||||||

and if two neutron stars come close enough together, ||||||||разом

spiral together and merge, |||злиття

they release tidal waves of these free neutrons. вони|||||||

Exactly the ingredients Саме||інгредієнти

to take those big leaps across the periodic table. |||||через|||таблиця

Creating new elements and merging neutron stars Створення нових елементів||||злиття||

used to be purely theoretical, використовувався||||

but in recent years |||роки

we've actually witnessed these collisions ||||зіткнення

and felt their gravitational aftershocks. ||||післяшоки

The light given off by one merger цей||||||

900 million light-years away confirmed

that heavy elements like gold що||||золото

do form during these violent events. |||||подіях

Sometimes enough to make 10 Earth's worth of gold іноді||||Землі|вартість||

in a single merger. |||злиття

Is this same process true for rhodium too? |||||||теж

Well, we don't really know, but scientists think Ну|||||||

that it's likely colliding neutron stars could, ||||||могли

in fact, be where most of the heavy metal end в|факт|бути|||||||

of the periodic table is born. |||||народився

But there's still much about these processes Але||||||

that scientists don't fully understand. ||||не повністю розуміють

Rhodium and some of its rare neighbors,

they likely form in other ways too,

perhaps somewhere in between these rapid and slow processes.

But even in a universe

that's experienced several generations of dying stars

across nearly 14 billion years of existence,

these explosive atomic nurseries are rare |||дитячі садки||

and pretty spread out.

Across the universe, elements made in these processes

are about a million times more scarce