Kind: captions
Language: en
This video was sponsored
by Caséta by Lutron.
Imagine you have a giant circuit
consisting of a battery,
a switch, a light bulb,
and two wires which are each
300,000 kilometers long.
That is the distance light
travels in one second.
So, they would reach
out half way to the moon
and then come back to be
connected to the light bulb,
which is one meter away.
Now, the question is,
after I close this switch,
how long would it take
for the bulb to light up.
Is it half a second,
one second,
two seconds,
1/c seconds,
or none of the above.
You have to make some
simplifying assumptions
about this circuit,
like the wires have to have no resistance,
otherwise this wouldn't work
and the light bulb has
to turn on immediately
when current passes through it.
But I want you to commit to an answer
and put it down in the comments
so you can't say,
oh yeah I knew that was the answer,
when I tell you the answer later on.
This question actually relates
to how electrical energy
get from a power plant to your home.
Unlike a battery,
the electricity in the grid
comes in the form of
alternating current, or AC,
which means electrons in the power lines
are just wiggling back and forth.
They never actually go anywhere.
So, if the charges don't
come from the power plant
to your home,
how does the electrical
energy actually reach you?
When I used to teach this subject,
I would say that power lines
are like this flexible plastic tubing
and the electrons inside
are like this chain.
So, what a power station does,
is it pushes and pulls the
electrons back and forth
60 times a second.
Now, at your house,
you can plug in a device, like a toaster,
which essentially means
allowing the electrons to run through it.
So when the power station
pushes and pulls the electrons,
well, they encounter resistance
in the toaster element,
and they dissipate their energy as heat,
and so you can toast your bread.
Now, this is a great story,
I think it's easy to visualize,
and I think my students understood it.
The only problem is, it's wrong.
For one thing,
there is no continuous conducting wire
that runs all the way from a
power station to your house.
No, there are physical gaps,
there are breaks in the line,
like in transformers
where one coil of wire
is wrapped on one side,
a different coil of wire is
wrapped on the other side.
So, electrons cannot possibly flow
from one the other.
Plus, if it's the electrons
that are carrying the energy
from the power station to your device,
then when those same electrons
flow back to the power station,
why are they not also carrying energy
back from your house to the power station?
If the flow of current is two ways,
then why does energy only
flow in one direction?
These are the lies you were
taught about electricity,
that electrons themselves
have potential energy,
that they are pushed or pulled
through a continuous conducting loop
and that they dissipate
their energy in the device.
My claim in this video
is that all of that is false.
So, how does it actually work?
In the 1860's and 70's,
there was a huge breakthrough
in our understanding of the universe
when Scottish physicist,
James Clerk Maxwell,
realized that light is made up
of oscillating electric
and magnetic fields.
The fields are oscillating
perpendicular to each other
and they are in phase,
meaning when one is at its maximum,
so is the other wave.
Now, he works out the equations
that govern the behavior of
electric and magnetic fields
and hence, these waves,
those are now called Maxwell's equations.
But in 1883,
one of Maxwell's former
students, John Henry Poynting,
is thinking about conversation of energy.
If energy is conserved locally
in every tiny bit of space,
well, then you should be
able to trace the path
that energy flows from
one place to another.
So, think about the energy
that comes to us from the sun,
during those eight minutes
when the light is traveling,
the energy is stored and being transmitted
in the electric and magnetic
fields of the light.
Now, Poynting works out an equation
to describe energy flux,
that is, how much electromagnetic energy
is passing through an area per second.
This is known as the Poynting vector
and it's given the symbol S.
And the formula is really pretty simple,
it's just a constant one over mu naught,
which is the permeability of free space
times E X B.
Now, E X B,
is the cross product
of the electric and magnetic fields.
Now, the cross product
is just a particular way
of multiplying two vectors together,
where you multiply their
perpendicular magnitudes
and to find the direction,
you put your fingers in the
direction of the first vector,
which in this case is the electric field,
and curl them in the direction
of the second vector,
the magnetic fields,
then your thumb points
in the direction of the resulting vector,
the energy flux.
So, what this shows us about light
is that the energy is
flowing perpendicular
to both the electronic
an the magnetic fields.
And it's in the same direction
as the light is traveling,
so this makes a lot of sense.
Light carries energy from its source
out to its destination.
But the kicker is this,
Poynting's equation doesn't
just work for light,
it works anytime there are electric
and magnetic fields coinciding.
Anytime you have electric
and magnetic fields together,
there is a flow of energy
and you can calculate
using Poynting's vector.
To illustrate this,
let's consider a simple circuit
with a battery and a light bulb.
The battery by itself
has an electric field
but since no charges are moving,
there is no magnetic field
so the battery doesn't lose energy.
When the battery is
connected into the circuit,
its electric field extends
through the circuit
at the speed of light.
This electric field
pushes electrons around
so they accumulate on some of
the surfaces of the conductors
making them negatively charged,
and are depleted elsewhere
leaving their surfaces positively charged.
These surface charges
create a small electric
field inside the wires,
causing electrons to drift
preferentially in one direction.
Note that this drift
velocity is extremely slow
around a tenth of a millimeter per second.
But this is current,
well, conventional current
is defined to flow opposite
the motion of electrons,
but this is what's making it happen.
The charge on the
surfaces of the conductors
also creates an eclectic
field outside the wires
and the current inside the wires
creates a magnetic
field outside the wires.
So, now there is a combination
of electric and magnetic fields
in this space around the circuit.
So, according to Poynting's theory,
energy should be flowing
and we can work out the
direction of this energy flow
using the right hand rule.
Around the battery for example,
the electric field is down
and the magnetic field is into the screen.
So, you find the energy
flux is to the right
away from the battery.
In fact, all around the battery,
you'll find the energy
is radially outwards.
Energy is going out through
the sides of the battery
into the fields.
Along the wires, again,
you can use the right hand rule
to find the energy is
flowing to the right.
This is true for the
fields along the top wire
and the bottom wire.
But at the filament,
the Poynting vector is directed
in toward the light bulb.
So, the light bulb is getting
energy from the field.
If you do the cross product,
you find the energy is coming
in from all around the bulb.
It takes many paths from
the battery to the bulb,
but in all cases,
the energy is transmitted
by the electric and magnetic fields.
- People seem to think that
you're pumping electrons
and that you're buying
electrons or something,
which is just so wrong. (laughs)
For most people,
and I think to this day,
it's quite counterintuitive
to think that the energy is
flowing through the space
around the conductor,
but the energy is,
which is traveling through the field,
yeah, is going quite fast.
- So, there are a few
things to notice here.
Even though the electrons go two ways
away from the battery and towards it,
by using the Poynting vector,
you find that the energy
flux only goes one way
from the battery to the bulb.
This also shows it's the fields
and not the electrons
that carry the energy.
- How far do the electrons go
in this little thing you're talking about,
they barely move,
they probably don't move at all.
- Now, what happens if
in place of a battery,
we use an alternating current source?
Well then, the direction of current
reverses every half cycle.
But this means that both the
electric and magnetic fields
flip at the same time,
so at any instant,
the Poynting vector still
points in the same direction,
from the source to the bulb.
So the exact same analysis we used for DC
still works for AC.
And this explains how
energy is able to flow
from power plants to home in power lines.
Inside the wires,
electrons just oscillate back and forth.
Their motion is greatly exaggerated here.
But they do not carry the energy.
Outside the wires,
oscillating eclectic and magnetic fields
travel from the power
station to your home.
You can use the Poynting vector to check
that the energy flux is
going in one direction.
You might think this is
just an academic discussion
that you could see the
energy as transmitted
either by fields or by
the current in the wire.
But that is not the case,
and people learned this the hard way
when they started laying
undersea telegraph cables.
The first Trans Atlantic
cable was laid in 1858.
- It only worked for about a month,
it never worked properly.
- There are all kinds of distortions
when they try to send signals.
- Enormous amounts of distortion.
They could work it at
a few words per minute.
- What they found was sending signals
over such a long distance under the sea,
the pulses became
distorted and lengthened.
It was hard to differentiate
dots from dashes.
To account for the failure,
there was a debate among scientists.
William Thomson, the future Lord Kelvin,
thought electrical signals
moved through submarine cables
like water flowing through a rubber tube.
But others like Heaviside and Fitzgerald,
argued it was the fields around the wires
that carried the energy and information.
And ultimately,
this view proved correct.
To insulate and protect
the submarine cable,
the central copper conductor
had been coated in an insulator
and then encased in an iron sheath.
The iron was only meant
to strengthen the cable,
but as a good conductor,
it interfered with a propagation
of electromagnetic fields
because it increased the
capacitance of the line.
This is why today, most power
lines are suspended high up.
Even the damp earth acts as a conductor,
so you want a large insulating gap of air
to separate the wires from the ground.
So, what is the answer
to our giant circuit light bulb question?
Well, after I close the switch,
the light bulb will turn
on almost instantaneously,
in roughly 1/C seconds.
So, the correct answer is D.
I think a lot of people imagine
that the electric field needs to travel
from the battery,
all the way down the wire
which is a light second long,
so it should take a second
for the bulb to light up.
But what we've learned in this video
is it's not really what's
happening in the wires
that matters,
it's what happens around the wires.
And the electric and magnetic fields
can propagate out through space
to this light bulb,
which is only one meter
away in a few nanoseconds.
And so, that is the limiting factor
for the light bulb turning on.
Now, the bulb won't receive
the entire voltage of
the battery immediately,
it'll be some fraction,
which depends on the
impedance of these lines
and the impedance of the bulb.
Now, I asked several
experts about this question,
and got kind of different answers,
but we all agreed on these main points.
So, I'm gonna put their
analysis in the description
in case you want to learn more
about this particular setup.
If I get called out on it
and people don't think it's real,
we can definitely invest the resources
and string up some lines,
and make our own power
lines in the desert.
- I think you're gonna
get called out on it.
- I agree, I think you're
gonna get called out.
(laughing)
I think that's right.
- I think it's just kinda wild
that this is one of those things
that we use everyday,
that almost nobody thinks about
or knows the right answer to.
These traveling electromagnetic
waves around power lines
are really what's delivering your power.
Hey, now that you understand
how electrical energy actually flows,
you can think about that
every time you flick on a light switch.
And if you want to take your
switches to the next level,
the sponsor of this
video, Caseta by Lutron,
provides premium smart lighting control,
including switches, remotes,
and plug-in smart dimmers.
And since one switch can
control many regular bulbs,
you can effectively make
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Then, you can turn your lights on and off
using your phone,
or you can use another device
like Alexa or Google Assistant.
Caseta works with more
leading smart home brands
than any other smart
lighting control system.
One of the things I
like is setting timers.
The lights in my office for example,
turn on by themselves every evening.
And this feature gives you peace of mind
that everyone in your household
will always come home to a well-lit house.
And once you're already in bed,
you can check which lights
you forgot to turn off
and do that from your phone.
Installation is easy.
Make sure you turn off
power to the switch first
and then disconnect the existing wires
and connect Caseda's smart switch.
If you need any help,
they're just a click or a call away.
Learn more about Caseda
at Lutron's website,
lutron.com/veritasium.
I will put that link
down in the description.
So, I want to thank Lutron Electronics
for sponsoring this video,
and I want to thank you for watching.