Electromagnetic Waves & Electromagnetic Spectrum Video Lecture | Electromagnetics - Electronics and Communication Engineering (ECE)

- You might note that if you've got
a positive charge sitting out in space
it's gonna create an Electric field,
and that Electric field is
gonna point radially outward
away from the positive charge.
And you might note that if
you've got a current in a wire,
that current is gonna
create a Magnetic field,
and that Magnetic field is
gonna loop around that wire
it's gonna look something like this.
But people started to realize
there is another way to
create a Magnetic field
besides having a current,
and there's another way to
create an Electric field
besides having charges.
Turns out if you have a
changing Electric field
in some region of space,
even if that region has no current in it,
by the fact that it has a
change in Electric field
that's going to induce or
create a Magnetic field.
So here was a way to
create a Magnetic field
that didn't even required a current,
it just required a change in
Electric field in that region.
And people also started to realize
if you've got a changing Magnetic field,
that is gonna create a
changing Electric field.
And a very clever Scottish physicist
named James Clerk Maxwell realized,
hold on, if this is true,
if a changing Electric field
can create a changing Magnetic field,
and a changing Magnetic
field could in turn
create a changing Electric field,
which could in turn create
a changing Magnetic field,
then you could set up some
sort of chain reaction here
that can propagate like a wave,
and you would get a wave
of Electric and Magnetic fields
that can travel outward and have
sort of an independent existence now
from whatever parent current
or parent charge created them.
So how would you create a
changing Electric field?
You could take this charge
and sort of wiggle it upside do--
Up and down.
Sounds like an antenna,
that's what you could do, an antenna,
that would create a
changing Electric field,
and then a changing Magnetic field,
and this could propagate outward.
And similarly you could have a current,
how could you create a
changing Magnetic field?
Just have this current oscillate
back and forth, changing,
that would create a
changing Magnetic field
which would create a
changing Electric field,
then it could propagate outward
and now this wave could have
its own independent existence
and keep moving forward at some speed.
And we call these
Electromagnetic waves because
"Electro", they have Electric fields,
and "magnetic" because
they have Magnetic fields,
and waves because they propagate outward
according to wave equations and
similar to all the other
waves that we've seen.
There is one difference,
these waves don't actually need a medium,
they can travel through straight vacuum,
you don't need actual particles
of some stuff in here,
these can move through the vacuum,
which is a little weird
because the only thing that's waving here,
the only thing that's oscillating
is the value of the Electric
and Magnetic fields.
And so these are Electromagnetic waves,
this is a pretty horrible drawing of it,
it looks a little bit more like this.
These yellow lines represent
the Magnetic fields,
these are directed up and down,
they point up and down,
they don't stick out up and down,
I just had to draw it that way
but what I'm trying say is that
this point right here,
it's not that there's a
Magnetic field that sticks up,
it points up,
and I'll just draw with a bigger vector
to show that at this point right here
along with this axis,
this axis could be, say the x direction,
so if this is the x direction,
and at this position in space
there would be a relatively
large Magnetic field
it would point up.
And these red lines
represent the Electric field,
so at this point in space
there'd be a relatively
large Electric field,
and the Electric field is at
a right angle to the Magnetic field,
so these are perpendicular,
that's how this process has to happen.
It's gonna create an
Electric and Magnetic field
that are perpendicular to each other,
so the Electric field sticks out,
this is pointing, think of it
as out of your computer
screen or your screen,
or whatever you're watching this on.
And these Electric fields back
here point into the screen.
And so this is in 3D,
this is happening in 3D,
Electric field oscillating
into and out of your screen,
Magnetic field oscillating up and down,
and the whole wave traveling to the right.
So this whole thing happens,
all three of these
directions are right angles,
so if I imagine a
three-dimensional axes here,
so x, y, z,
this would be the direction
of the speed of this
or the velocity of this wave,
it doesn't have to point in this direction
but whatever direction it's pointing
you'd have velocity in one direction,
you'd have Magnetic field
in the other direction,
and you'd have Electric field
in one more perpendicular direction,
all three of these are
perpendicular to each other.
So the Magnetic field is perpendicular
to the Electric field,
the Electric field is perpendicular
to the Magnetic field,
then both the Magnetic
and the Electric fields
are perpendicular to the direction
that the Electromagnetic
wave is traveling.
And the speed at which these waves travel
is the speed of light, c,
and by c I mean three
times 10 to the eight
meters per second,
because light is just
and Electromagnetic wave,
light is a special example,
one particular example
of Electromagnetic waves,
but it is only one example,
these waves can have any wavelength.
Look, from here to here,
this, since this is in space,
the graph of the wave and
along a special direction,
this would represent the wavelength.
These waves could have any wavelength,
any particular wavelength,
and any particular frequency.
They frequency would be the rate
at which these change.
So if you'd watch this in time,
this point in space would
have a Magnetic field
that would point up,
then it would point down,
then it would point up,
then it would point down,
and the rate at which that's happening,
the number of times per
second would be the frequency.
These waves could have any frequency,
but for one special region,
the region is the visible spectrum.
So we call the regional frequencies
and wavelengths that
Electromagnetic waves can have
the Electromagnetic Spectrum,
and there is a lot to learn
about the Electromagnetic Spectrum.
Let me just show you really quick.
If we pretend we're graphing
here, along this line,
higher frequency.
So let's say in that direction
this is pointing higher
frequencies to the right,
in other words higher Hertz
since that's what we measure frequency in.
But if that's higher frequency,
because of this formula,
speed of a wave is lambda
times frequency wavelength,
times frequency.
If the frequency increases the
wavelength has to decrease,
so in this right way direction
this would be smaller wavelength,
and wavelength is measured in meters
but when you're talking about light,
since you have such small wavelengths
you often talk about nanometers.
So, where would the visible spectrum be?
The visible spectrum would just be
this little smudge here in our range,
this would be the...
This whole thing is called
the Electromagnetic Spectrum,
so the Electromagnetic Spectrum,
and the visible spectrum
is just right here.
This would be the visible spectrum,
so this is visible,
between red and violet.
And red is, if I asked you
what frequency that is,
that would be around four times
10 to the fourteenth Hertz,
and violet would be around
7.5 times 10 to the fourteenth Hertz.
Or if you wanted to talk about wavelength,
red would be around 750 nanometers,
and violet would be around 400 nanometers,
and by nano we mean 10
to the negative ninth.
Okay, but this is just a small region,
you could have higher
frequencies than violet,
and what do we call those?
We call those ultraviolet,
and we know these are bad for us,
and they're bad for us because
as we go to the right here,
higher frequencies,
turns out this also means
more energetic light.
So if you were to talk about the photons
that make up this light,
if you're talking about quantum mechanic
those photons as you go forward,
higher up into the frequencies,
have more energy,
that means that they're more dangerous,
and they're more dangerous because
if they have more energy
they can add that energy
to your cells and break
them apart and cause damage,
and so this causes problems
as you go further up this way,
so we put on sunscreen
to protect ourselves
from ultraviolet light.
But this isn't the highest frequency,
you can have much higher frequencies,
you can have X-Rays,
X-Rays are even higher frequency,
even more dangerous,
which is why X-Ray technicians,
you go in there and they're like,
"hey, stand right here,
"I'm going to get your X-Ray
"while I hide behind this wall",
because if they had to sit there
and take that X-Ray every single day
it would really be bad for them.
But this isn't even the highest,
you've got things called Gamma Rays,
and Gamma Rays are
unbelievably energetic light,
and these are very dangerous.
These happens, these come from space
or from some sort of nuclear reaction.
These are extremely dangerous, Gamma Rays,
that's why you always
hear them in comic books,
people wanna blame like
why some hero was created,
they say, "oh, that was a Gamma Ray",
'cause it just sounds really powerful.
It won't turn people into superheroes
but it's very energetic.
Then down here you've got infrared,
so this would be below red.
You couldn't see these either,
could be either infrared,
and then below that you've got microwaves,
and microwaves, in this region
there's a lot of useful stuff,
your cellphones signals,
they're in the microwave region,
TV signals that are sent through the air
in the microwave region,
this is used for a lot of cases.
And then below this
you've got radio waves,
even though technically
speaking FM radio waves
are more in the microwave region,
these are more like AM,
so when people started first making radio
they used frequencies down here,
and that was the AM frequency range.
So this is the Electromagnetic Spectrum,
the visible range is a small region of it,
we can't see anything outside of that,
but these are extremely useful
in a lot of different cases,
and dangerous, you need to know about
the Electromagnetic Spectrum.