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PROFESSOR: All right.

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00:00:22,260 --> 00:00:24,870
As you're settling in, why don't
you take 10 more seconds

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00:00:24,870 --> 00:00:26,950
to answer the clicker
question.

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00:00:26,950 --> 00:00:29,470
This is the last question we'll
see in class on the

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00:00:29,470 --> 00:00:32,780
photoelectric effect, so
hopefully we can have a very

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high success rate here to show
we are all ready to move on

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00:00:36,110 --> 00:00:42,410
with our lives here.

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00:00:42,410 --> 00:00:43,250
OK, good.

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00:00:43,250 --> 00:00:46,480
So, most of you did get
the answer correct.

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00:00:46,480 --> 00:00:50,460
For those of you that didn't,
you, of course, can ask your

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00:00:50,460 --> 00:00:52,890
TA's about this in recitation,
they'll always have a copy of

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00:00:52,890 --> 00:00:53,860
these slides.

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00:00:53,860 --> 00:00:56,280
But just to point out the
confusion can be we've

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00:00:56,280 --> 00:00:58,660
actually switched what
the question is here.

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00:00:58,660 --> 00:01:01,950
What the information we gave was
the work function, which

23
00:01:01,950 --> 00:01:04,610
is what we've been giving
before, but now we gave you

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00:01:04,610 --> 00:01:07,350
the kinetic energy of the
ejected electron, so you just

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00:01:07,350 --> 00:01:09,980
need to rearrange your equation
so now you're solving

26
00:01:09,980 --> 00:01:12,190
for the incoming energy, which
would mean that you need to

27
00:01:12,190 --> 00:01:13,810
add those two energies
together.

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00:01:13,810 --> 00:01:16,950
So, hopefully everyone that
didn't get this right, can

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00:01:16,950 --> 00:01:19,130
look at it again and think about
asking it's just asking

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00:01:19,130 --> 00:01:21,610
the question in a different
kind of a way.

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00:01:21,610 --> 00:01:21,940
All right.

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00:01:21,940 --> 00:01:24,550
So, we can switch over
to the class notes.

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00:01:24,550 --> 00:01:26,630
So today, we're going to
start talking about

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00:01:26,630 --> 00:01:27,880
the hydrogen atom.

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00:01:27,880 --> 00:01:30,500
Now that we have our Schrodinger
equation for the

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00:01:30,500 --> 00:01:33,740
hydrogen atom, we can talk about
it very specifically in

37
00:01:33,740 --> 00:01:37,170
terms of binding energies and
also in terms of orbitals.

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00:01:37,170 --> 00:01:40,350
And we talked about on Wednesday
the conditions that

39
00:01:40,350 --> 00:01:43,450
allowed us to use quantum
mechanics, which then enable

40
00:01:43,450 --> 00:01:45,970
us to have the Schrodinger
equation, which we can apply,

41
00:01:45,970 --> 00:01:48,520
and part of that is the
wave particle duality

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00:01:48,520 --> 00:01:50,020
of light and matter.

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00:01:50,020 --> 00:01:56,450
So there was a good question in
Wednesday's class about the

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00:01:56,450 --> 00:01:58,090
de Broglie wavelength
and if it can

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00:01:58,090 --> 00:01:59,200
actually go to infinity.

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00:01:59,200 --> 00:02:01,380
So I just wanted to address that
quickly before we move

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00:02:01,380 --> 00:02:05,610
on, and actually address another
thing about dealing

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00:02:05,610 --> 00:02:08,660
with wavelengths of particles
that sometimes comes up.

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00:02:08,660 --> 00:02:16,110
So, the question that we had in
last class, was if we have

50
00:02:16,110 --> 00:02:19,370
actually a macroscopic particle,
and the velocity

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00:02:19,370 --> 00:02:22,670
let's say starts to approach
zero, shouldn't we have the

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00:02:22,670 --> 00:02:26,840
wavelength go to infinity, even
if we have a magic board,

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00:02:26,840 --> 00:02:29,660
and even if the mass
is really large.

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00:02:29,660 --> 00:02:32,880
So, in most cases, you would
think that as the velocity

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00:02:32,880 --> 00:02:38,230
gets very tiny, the mass is
still going to be large enough

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00:02:38,230 --> 00:02:41,490
to cancel it out and still
make it such that the

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00:02:41,490 --> 00:02:43,730
wavelength is going to be
pretty small, right.

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00:02:43,730 --> 00:02:47,950
Because if we think about the
h, Planck's constant, here

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that's measured in 10 to the
negative 34 joules per second.

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00:02:52,040 --> 00:02:54,740
So, we would actually need a
really, really, really tiny

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velocity here to actually
overcome the size of the mass,

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00:02:59,540 --> 00:03:02,195
if we're talking about
macroscopic particles, to have

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00:03:02,195 --> 00:03:04,380
a wavelength that's going
to be on the order.

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So, let's say we're talking
about the baseball, have a

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wavelength of the baseball
that's on the

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order of the baseball.

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00:03:10,060 --> 00:03:13,290
So, if we kind of think about
the numbers we would need, we

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00:03:13,290 --> 00:03:16,030
would actually need a velocity
that approached something

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00:03:16,030 --> 00:03:20,310
that's about 10 to the negative
30 meters per second.

70
00:03:20,310 --> 00:03:23,640
So first of all, that's
pretty slow here.

71
00:03:23,640 --> 00:03:26,920
It's going to be hard to measure
anyway, and in fact,

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00:03:26,920 --> 00:03:29,640
if we're talking about something
going 10 to the

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00:03:29,640 --> 00:03:33,310
negative 30, and we're going to
observe it using our eyes,

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so you using visible light to
observe something going this

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slow, we're actually not going
to be able to do it because

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we're limited by the wavelength
of light to see how

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00:03:41,880 --> 00:03:45,000
precise we can measure where
the actual position is.

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So let's say we have the
wavelength of light somewhere

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on the order of 10 to the
negative 5 meters, being the

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00:03:51,010 --> 00:03:54,030
wavelength of light, we're
only going to be able to

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00:03:54,030 --> 00:03:57,420
measure the velocity because of
the uncertainty principle

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to a certain degree.

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00:03:58,590 --> 00:04:05,070
And it turns out it's three
orders of magnitude that --

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00:04:05,070 --> 00:04:07,460
the uncertainty is three orders
of magnitude bigger

85
00:04:07,460 --> 00:04:10,060
than the velocity that we're
actually trying to observe to

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00:04:10,060 --> 00:04:12,640
get to a point where we could
see the wavelength, for

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00:04:12,640 --> 00:04:16,240
example, for even a baseball
that is moving this slow?

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00:04:16,240 --> 00:04:19,330
So that the more complete answer
to the question is that

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00:04:19,330 --> 00:04:21,960
no, we're never going to be able
to observe that because

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00:04:21,960 --> 00:04:25,165
of the uncertainty principle
it's not possible to observe a

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00:04:25,165 --> 00:04:27,680
velocity that's this slow for
a macroscopic object.

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00:04:27,680 --> 00:04:32,510
So, hopefully that kind of
clears up that question.

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00:04:32,510 --> 00:04:34,820
And, of course, when the
velocity actually is zero,

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00:04:34,820 --> 00:04:38,350
this equation that the de
Broglie has put forth is valid

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00:04:38,350 --> 00:04:40,900
for anything that has momentum,
so if something does

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00:04:40,900 --> 00:04:43,290
not have any velocity at all,
it actually does not have

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00:04:43,290 --> 00:04:46,540
momentum, so you can't apply
that equation anyway.

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00:04:46,540 --> 00:04:50,770
And another thing that came
up, and it came up in

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00:04:50,770 --> 00:04:54,140
remembering as I was writing
your problem set for this

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00:04:54,140 --> 00:04:56,510
week, which will be posted
sometime this afternoon, your

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00:04:56,510 --> 00:04:59,910
problem set 2, is when we're
talking about wavelengths of

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00:04:59,910 --> 00:05:02,550
particles, and for specifically
for electrons

103
00:05:02,550 --> 00:05:05,320
sometimes, you're asked to
calculate what the energy is.

104
00:05:05,320 --> 00:05:07,820
And I just want to remind
everyone, so this is a

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00:05:07,820 --> 00:05:13,550
separate thought here, that we
often use the energy where

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00:05:13,550 --> 00:05:18,210
energy is equal to h c divided
by wavelength.

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00:05:18,210 --> 00:05:21,290
So if we're talking about,
for example, we know the

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00:05:21,290 --> 00:05:23,530
wavelength of an electron and
we're trying to find the

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00:05:23,530 --> 00:05:26,300
energy or vice versa, is
this an equation we

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00:05:26,300 --> 00:05:28,640
can use to do that?

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What do you think?

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00:05:31,390 --> 00:05:31,960
No.

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00:05:31,960 --> 00:05:33,870
Hopefully you're going
to say no.

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00:05:33,870 --> 00:05:37,190
And the reason is, and this will
come up on the problems

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00:05:37,190 --> 00:05:39,670
and a lot of students end up
using this equation, which is

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00:05:39,670 --> 00:05:42,420
why I want to head it off and
mention it ahead of time, we

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00:05:42,420 --> 00:05:45,100
can't use an equation because
this equation is very

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00:05:45,100 --> 00:05:46,370
specific for light.

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00:05:46,370 --> 00:05:50,120
We know it's very specific for
light because in this equation

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00:05:50,120 --> 00:05:52,060
is c, the speed of light.

121
00:05:52,060 --> 00:05:54,590
So any time you go to use this
equation, if you're trying to

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00:05:54,590 --> 00:05:57,870
use it for an electron, just
ask yourself first, does an

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00:05:57,870 --> 00:06:00,030
electron travel at the
speed of light?

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00:06:00,030 --> 00:06:04,160
And if your answer is no, your
answer will be no, then you

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00:06:04,160 --> 00:06:06,470
just know you can't use
this equation here.

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00:06:06,470 --> 00:06:09,660
So instead you'd have to maybe
if you start with wavelength,

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00:06:09,660 --> 00:06:12,580
go over there, and then figure
out velocity and do something

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00:06:12,580 --> 00:06:15,460
more like kinetic energy
equals 1/2 n b

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00:06:15,460 --> 00:06:16,660
squared to get there.

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00:06:16,660 --> 00:06:18,835
So this is just a heads up
for as you start your

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next problem set.

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00:06:21,170 --> 00:06:21,500
All right.

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00:06:21,500 --> 00:06:25,750
So jumping in to having
established that, yes,

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00:06:25,750 --> 00:06:28,570
particles have wave-like
behavior, even though no,

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00:06:28,570 --> 00:06:31,460
they're not actually photons,
we can't use that equation.

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00:06:31,460 --> 00:06:36,110
But we can use equations that
describe waves to describe

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matter, and that's what we're
going to be doing today.

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00:06:38,410 --> 00:06:40,570
We're going to be looking
at the solutions to the

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00:06:40,570 --> 00:06:42,740
Schrodinger equation for
a hydrogen atom, and

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00:06:42,740 --> 00:06:45,690
specifically we'll be looking
at the binding energy of the

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00:06:45,690 --> 00:06:47,380
electron to the nucleus.

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00:06:47,380 --> 00:06:49,640
So we'll be looking at the
solution to this part of the

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00:06:49,640 --> 00:06:52,130
Schrodinger equation where
we're finding e.

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00:06:52,130 --> 00:06:54,780
Then we'll go on, after we've
made all of our predictions

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00:06:54,780 --> 00:06:57,770
for what the energy should be,
we can actually confirm

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00:06:57,770 --> 00:07:00,200
whether or not we're correct,
and we'll do this by looking

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00:07:00,200 --> 00:07:04,490
at photon emission and photon
absorption for hydrogen atoms,

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00:07:04,490 --> 00:07:07,110
and we'll actually do a demo
with that, too, so we can

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00:07:07,110 --> 00:07:10,240
confirm it ourselves, as well
as matching it with the

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00:07:10,240 --> 00:07:12,080
observation of others.

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00:07:12,080 --> 00:07:15,060
And if we have time, we'll move
on also to talking about

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the other part of the solution
to the Schrodinger equation,

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00:07:17,780 --> 00:07:21,120
which is psi or this
wave function here.

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00:07:21,120 --> 00:07:23,420
And remember I said that
wave function is just a

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00:07:23,420 --> 00:07:26,460
representation of the particle,
particularly when

156
00:07:26,460 --> 00:07:29,400
we're talking about electrons
-- we're familiar with the

157
00:07:29,400 --> 00:07:34,460
term orbitals. psi is just a
description of the orbital.

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00:07:34,460 --> 00:07:36,740
So, we'll start with an
introduction to that if we got

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00:07:36,740 --> 00:07:39,270
to it at the end.

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00:07:39,270 --> 00:07:41,450
So, to remind you, when we
look at the Schrodinger

161
00:07:41,450 --> 00:07:46,110
equation here, we have two parts
to it, so when we solve

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00:07:46,110 --> 00:07:48,980
the Schrodinger equation, we're
either finding psi,

163
00:07:48,980 --> 00:07:52,950
which as I said, is a wave
function or an orbital.

164
00:07:52,950 --> 00:07:57,070
And in addition to finding psi,
we can also solve to find

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00:07:57,070 --> 00:08:00,960
e or to find the energy for any
given psi, and these are

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00:08:00,960 --> 00:08:04,440
the binding energies of the
electron to the nucleus.

167
00:08:04,440 --> 00:08:06,840
And the most important thing
about using the Schrodinger

168
00:08:06,840 --> 00:08:09,180
equation and getting out our
solutions for potential

169
00:08:09,180 --> 00:08:12,170
orbitals and potential energies
for an electron with

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00:08:12,170 --> 00:08:15,050
the nucleus, is that what
we find is that quantum

171
00:08:15,050 --> 00:08:17,750
mechanics, and quantum mechanics
allowing us to get

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00:08:17,750 --> 00:08:21,140
to the Schrodinger equation,
allows us to correctly predict

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00:08:21,140 --> 00:08:24,450
and confirm our observations
for what we can actually

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00:08:24,450 --> 00:08:27,620
measure are indeed the
energy levels.

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00:08:27,620 --> 00:08:29,923
Here we're talking about a
hydrogen atom and that's what

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00:08:29,923 --> 00:08:30,940
we'll focus on today.

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00:08:30,940 --> 00:08:33,550
And it's incredibly precise
and we're able to make the

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00:08:33,550 --> 00:08:35,860
predictions and match them
with experiment.

179
00:08:35,860 --> 00:08:38,270
Also, when we're looking at the
Schrodinger equation, it

180
00:08:38,270 --> 00:08:42,020
allows us to explain a stable
hydrogen atom, which is

181
00:08:42,020 --> 00:08:43,560
something that classical
mechanics did

182
00:08:43,560 --> 00:08:46,760
not allow us to do.

183
00:08:46,760 --> 00:08:51,420
So here's the solution for a
hydrogen atom, where we have

184
00:08:51,420 --> 00:08:55,040
the e term here is equal to
everything written in green.

185
00:08:55,040 --> 00:08:58,260
We've got a lot of constants
in this solution to the

186
00:08:58,260 --> 00:09:01,330
hydrogen atom, and we know
what most of these mean.

187
00:09:01,330 --> 00:09:04,850
But remember that this whole
term in green here is what is

188
00:09:04,850 --> 00:09:07,480
going to be equal to that
binding energy between the

189
00:09:07,480 --> 00:09:11,230
nucleus of a hydrogen atom
and the electron.

190
00:09:11,230 --> 00:09:14,430
So, let's go ahead and define
our variables here, they

191
00:09:14,430 --> 00:09:17,830
should be familiar to us.

192
00:09:17,830 --> 00:09:23,570
We have the mass, first of all,
m is equal to m e, so

193
00:09:23,570 --> 00:09:29,360
that's the electron mass.

194
00:09:29,360 --> 00:09:33,670
We also have e, which
is going to be the

195
00:09:33,670 --> 00:09:40,010
charge on the electron.

196
00:09:40,010 --> 00:09:43,040
In addition to that, we have
that epsilon nought value,

197
00:09:43,040 --> 00:09:45,820
remember that's the permittivity
constant in a

198
00:09:45,820 --> 00:09:50,330
vacuum, and basically that is
what we use as a conversion

199
00:09:50,330 --> 00:09:51,820
factor to get from units.

200
00:09:51,820 --> 00:09:54,260
We don't want namely coulombs
to units, we want that will

201
00:09:54,260 --> 00:09:56,630
allow us to cancel out
in this equation.

202
00:09:56,630 --> 00:10:00,330
And finally we have Planck's
constant here, which we're all

203
00:10:00,330 --> 00:10:03,470
familiar with.

204
00:10:03,470 --> 00:10:07,140
So, what actually happens when
people work with the solution

205
00:10:07,140 --> 00:10:10,440
to the Schrodinger equation for
a hydrogen atom is that

206
00:10:10,440 --> 00:10:12,990
they don't always want to deal
with all these constants here,

207
00:10:12,990 --> 00:10:16,500
so we can actually group them
together and use them as a

208
00:10:16,500 --> 00:10:19,690
single new constant, and
this new constant

209
00:10:19,690 --> 00:10:21,450
is the Rydberg constant.

210
00:10:21,450 --> 00:10:25,940
And the Rydberg constant is
actually equal to 2 .

211
00:10:25,940 --> 00:10:30,410
1 8 times 10 to the negative
18 joules.

212
00:10:30,410 --> 00:10:33,050
So when we pull out all of those
constants and instead

213
00:10:33,050 --> 00:10:36,270
use the Rydberg constant, what
it allows us to do is really

214
00:10:36,270 --> 00:10:38,790
simplify our energy equation.

215
00:10:38,790 --> 00:10:41,890
So now we have that energy is
equal to the negative of the

216
00:10:41,890 --> 00:10:46,540
Rydberg constant divided
by n squared.

217
00:10:46,540 --> 00:10:49,330
So, what we have left in our
equation is only one part that

218
00:10:49,330 --> 00:10:52,320
we haven't explained yet, and
that is that n value.

219
00:10:52,320 --> 00:10:54,460
And it turns out that when
you solve the Schrodinger

220
00:10:54,460 --> 00:10:57,700
equation, you find that there
are only certain allowed

221
00:10:57,700 --> 00:10:59,470
values of this integer n.

222
00:10:59,470 --> 00:11:07,020
And those allowed values range
anywhere from n equals 1, you

223
00:11:07,020 --> 00:11:10,850
can have n equal that 2,
3, and it goes all

224
00:11:10,850 --> 00:11:12,360
the way up to infinity.

225
00:11:12,360 --> 00:11:14,970
But the important part is that
there are only certain allowed

226
00:11:14,970 --> 00:11:17,640
values, so for example,
you can't have 1 .

227
00:11:17,640 --> 00:11:18,720
5 or 2 .

228
00:11:18,720 --> 00:11:22,260
3, there are only these
interger numbers.

229
00:11:22,260 --> 00:11:24,660
And this n here is
what we call the

230
00:11:24,660 --> 00:11:34,630
principle quantum number.

231
00:11:34,630 --> 00:11:38,900
And what we find is when we
apply n and plug it in to our

232
00:11:38,900 --> 00:11:42,370
energy equation, is that what
we see is now we don't just

233
00:11:42,370 --> 00:11:45,810
have one distinct answer, we
don't just have one possible

234
00:11:45,810 --> 00:11:48,450
binding energy of the electron
to the nucleus.

235
00:11:48,450 --> 00:11:52,070
We're going to find that we
actually have a whole bunch of

236
00:11:52,070 --> 00:11:55,550
possible, in fact, an infinite
number of possible energy

237
00:11:55,550 --> 00:11:58,030
levels, and that's easier
to see on this

238
00:11:58,030 --> 00:12:00,700
energy diagram here.

239
00:12:00,700 --> 00:12:04,090
So, let's start with n equals
1, since that's, of course,

240
00:12:04,090 --> 00:12:05,270
the simplest case.

241
00:12:05,270 --> 00:12:08,450
So, if we have n equals 1, we
can plug it into our energy

242
00:12:08,450 --> 00:12:12,460
equation here, and find that the
binding energy, the e sub

243
00:12:12,460 --> 00:12:15,650
n, for n equals 1, it's just
going to be equal to the

244
00:12:15,650 --> 00:12:18,320
negative of the Rydberg
constant, so we can actually

245
00:12:18,320 --> 00:12:21,930
graph that on an energy diagram
here, and it's going

246
00:12:21,930 --> 00:12:25,010
to be down low at the bottom
because that's going to be, in

247
00:12:25,010 --> 00:12:27,650
fact, the lowest or most
negative energy

248
00:12:27,650 --> 00:12:30,100
when n equals 1.

249
00:12:30,100 --> 00:12:33,240
But we saw from our equation
that there's more than just

250
00:12:33,240 --> 00:12:36,530
one possible value for n, so we
could, for example, have n

251
00:12:36,530 --> 00:12:42,110
equals 2, n equals 3, all the
way up to n equaling infinity.

252
00:12:42,110 --> 00:12:46,160
So what this tells us here is
that this is not necessarily

253
00:12:46,160 --> 00:12:49,100
the binding energy of the
electron in a hydrogen atom,

254
00:12:49,100 --> 00:12:51,940
it's also possible that it
could, for example, have this

255
00:12:51,940 --> 00:12:54,640
energy, it could have this
energy up here, it could have

256
00:12:54,640 --> 00:12:56,390
some energy way up here.

257
00:12:56,390 --> 00:12:57,840
So we have this infinite
number of

258
00:12:57,840 --> 00:12:59,430
possible binding energies.

259
00:12:59,430 --> 00:13:01,110
But the really important
point here is

260
00:13:01,110 --> 00:13:02,550
that they're quantized.

261
00:13:02,550 --> 00:13:05,790
So it's not a continuum of
energy that we can have, it's

262
00:13:05,790 --> 00:13:08,850
only these punctuated points of
energy that are possible.

263
00:13:08,850 --> 00:13:12,350
So as I tried to say on the
board, we can have n equals 1,

264
00:13:12,350 --> 00:13:15,210
but since we can't have n equals
1/2, we actually can't

265
00:13:15,210 --> 00:13:19,140
have a binding energy that's
anywhere in between these

266
00:13:19,140 --> 00:13:20,980
levels that are indicated
here.

267
00:13:20,980 --> 00:13:23,390
And that's a really important
point for something that comes

268
00:13:23,390 --> 00:13:26,750
out of solving the Schrodinger
equation is this quantization

269
00:13:26,750 --> 00:13:29,130
of energy levels.

270
00:13:29,130 --> 00:13:32,620
And thanks to our equation
simplified here, it's very

271
00:13:32,620 --> 00:13:35,420
easy for us to figure out what
actually the allowed energy

272
00:13:35,420 --> 00:13:36,530
levels are.

273
00:13:36,530 --> 00:13:40,850
So for n equals 2, what would
the binding energy be?

274
00:13:40,850 --> 00:13:41,910
Someone shout it out.

275
00:13:41,910 --> 00:13:44,590
Yup.

276
00:13:44,590 --> 00:13:48,690
So, I think the compilation of
the voices that I heard was

277
00:13:48,690 --> 00:13:51,380
negative r h over 2 squared.

278
00:13:51,380 --> 00:13:54,930
We can do the same thing for 3,
negative r h over 3 squared

279
00:13:54,930 --> 00:13:57,170
is going to be our
binding energy.

280
00:13:57,170 --> 00:14:01,590
For 4, we can go all the way up
to infinity, and actually

281
00:14:01,590 --> 00:14:05,540
when we get to the point where
it's infinity, what we find is

282
00:14:05,540 --> 00:14:09,640
the binding energy at that point
is going to be zero.

283
00:14:09,640 --> 00:14:13,420
And when we get to infinity,
what that means is that we now

284
00:14:13,420 --> 00:14:17,620
have a free electron, so now
the electron has totally

285
00:14:17,620 --> 00:14:19,600
separated from the atom.

286
00:14:19,600 --> 00:14:22,580
And that makes sense because
we're at the point where

287
00:14:22,580 --> 00:14:25,640
there's no binding energy
keeping it stable.

288
00:14:25,640 --> 00:14:28,470
You'll also know that all of
these binding energies here

289
00:14:28,470 --> 00:14:32,050
are negative, so the negative
sign indicates that it's low.

290
00:14:32,050 --> 00:14:35,430
It's a more negative energy,
it's a lower energy state.

291
00:14:35,430 --> 00:14:37,800
So whenever we're thinking
about energy states, it's

292
00:14:37,800 --> 00:14:41,920
always more stable to be more
low in an energy well, so

293
00:14:41,920 --> 00:14:45,720
that's why it makes sense that
it's favorable, in fact, to

294
00:14:45,720 --> 00:14:48,720
have an electron interacting
with the nucleus that

295
00:14:48,720 --> 00:14:52,010
stabilizes and lowers
the energy of that

296
00:14:52,010 --> 00:14:55,000
electron by doing so.

297
00:14:55,000 --> 00:14:58,870
So, we actually term this n
equals 1 state gets a special

298
00:14:58,870 --> 00:15:02,230
name, which we call the ground
state, and it's called the

299
00:15:02,230 --> 00:15:05,300
ground state because it is, in
fact, the lowest to the ground

300
00:15:05,300 --> 00:15:05,950
that we can get.

301
00:15:05,950 --> 00:15:09,740
It's the most negative and most
stable energy level that

302
00:15:09,740 --> 00:15:14,900
we have. And when we think about
kind of in a more out

303
00:15:14,900 --> 00:15:17,980
practical sense what we mean
by all of these binding

304
00:15:17,980 --> 00:15:21,460
energies, another way that we
can put it is to give it some

305
00:15:21,460 --> 00:15:24,650
physical significance, and the
physical significance of

306
00:15:24,650 --> 00:15:28,540
binding energies is that they're
equal to the negative

307
00:15:28,540 --> 00:15:30,960
of the ionization energies.

308
00:15:30,960 --> 00:15:34,750
So, for example, in a hydrogen
atom, if you take the binding

309
00:15:34,750 --> 00:15:38,100
energy, the negative of that is
going to be how much energy

310
00:15:38,100 --> 00:15:41,990
you have to put in to ionize
the hydrogen atom.

311
00:15:41,990 --> 00:15:45,920
So, if, for example, we were
looking at a hydrogen atom in

312
00:15:45,920 --> 00:15:48,730
the case where we have the
n equals 1 state, so the

313
00:15:48,730 --> 00:15:52,740
electron is in that ground
state, the ionization energy,

314
00:15:52,740 --> 00:15:55,170
it makes sense, is going to be
the difference between the

315
00:15:55,170 --> 00:15:58,570
ground state and the energy it
takes to be a free electron.

316
00:15:58,570 --> 00:16:01,810
When we graph that on our chart
here, it becomes clear

317
00:16:01,810 --> 00:16:04,420
that yes, in fact, the
ionization energy is just the

318
00:16:04,420 --> 00:16:07,380
negative of the binding energy,
so we can just look

319
00:16:07,380 --> 00:16:11,410
over here and figure out what
our ionization energy is.

320
00:16:11,410 --> 00:16:14,160
So when we're talking about the
ground state of a hydrogen

321
00:16:14,160 --> 00:16:16,930
atom, our ionization energy is
just the negative of the

322
00:16:16,930 --> 00:16:19,430
Rydberg constant, so
that easy, it's 2 .

323
00:16:19,430 --> 00:16:23,590
1 8 times 10 to the negative
18 joules.

324
00:16:23,590 --> 00:16:26,420
So, that should make a lot of
sense intuitively, because it

325
00:16:26,420 --> 00:16:30,850
makes sense that if we need to
ionize an atom, we need to put

326
00:16:30,850 --> 00:16:35,110
energy into the atom in order
to eject that electron, and

327
00:16:35,110 --> 00:16:37,480
that energy we need to put in
better be the difference

328
00:16:37,480 --> 00:16:40,490
between where we are now and
where we have to be to be a

329
00:16:40,490 --> 00:16:44,140
free electron.

330
00:16:44,140 --> 00:16:47,830
So in most cases when we talk
about ionization energy, if we

331
00:16:47,830 --> 00:16:51,080
don't say anything specific to
the state we're talking about,

332
00:16:51,080 --> 00:16:53,820
you should always assume that we
are, in fact, talking about

333
00:16:53,820 --> 00:16:55,330
the ground state.

334
00:16:55,330 --> 00:16:58,220
So, oftentimes you'll just be
asked about ionization energy.

335
00:16:58,220 --> 00:17:01,180
If it doesn't say anything else
we do mean n equals 1.

336
00:17:01,180 --> 00:17:04,280
But, in fact, we can also talk
about the ionization energy of

337
00:17:04,280 --> 00:17:07,870
different states of the hydrogen
atom or of any atom.

338
00:17:07,870 --> 00:17:11,560
So, for example, we could talk
about the n equals 2 state, so

339
00:17:11,560 --> 00:17:14,400
that's this state here, and it's
also what we could call

340
00:17:14,400 --> 00:17:15,810
the first excited state.

341
00:17:15,810 --> 00:17:18,940
So we have the ground state, and
if we excite an electron

342
00:17:18,940 --> 00:17:21,380
into the next closest state,
we're at the first excited

343
00:17:21,380 --> 00:17:24,620
state, or the n equals
2 state.

344
00:17:24,620 --> 00:17:27,840
So, we can now calculate the
ionization energy here. it's

345
00:17:27,840 --> 00:17:30,910
an easy calculation -- we're
just taking the negative of

346
00:17:30,910 --> 00:17:33,510
the binding energy, again that
makes sense, because it's this

347
00:17:33,510 --> 00:17:35,610
difference in energy here.

348
00:17:35,610 --> 00:17:39,490
So what we get is that the
binding energy, when it's

349
00:17:39,490 --> 00:17:42,050
negative, the ionization
energy is 5 .

350
00:17:42,050 --> 00:17:46,580
4 5 times 10 to the negative
19 joules.

351
00:17:46,580 --> 00:17:49,050
So we should be able to think
about these binding energies

352
00:17:49,050 --> 00:17:51,660
and figure out the ionization
energy for any state that were

353
00:17:51,660 --> 00:17:52,320
asked about.

354
00:17:52,320 --> 00:17:55,920
So if we can switch over to a
clicker question here and

355
00:17:55,920 --> 00:17:58,720
we'll let you do that.

356
00:17:58,720 --> 00:18:02,690
And what we're asking you to
do is now tell us what the

357
00:18:02,690 --> 00:18:05,880
ionization energy is of a
hydrogen atom that is in its

358
00:18:05,880 --> 00:18:21,120
third excited state.

359
00:18:21,120 --> 00:18:21,330
All right.

360
00:18:21,330 --> 00:18:36,030
Let's take 10 more
seconds on that.

361
00:18:36,030 --> 00:18:36,710
OK.

362
00:18:36,710 --> 00:18:37,590
Interesting.

363
00:18:37,590 --> 00:18:40,280
Usually the majority is correct,
but actually what you

364
00:18:40,280 --> 00:18:43,620
did was illustrate a point that
I really wanted to stress

365
00:18:43,620 --> 00:18:45,880
and there's no better way to
stress it then to get it

366
00:18:45,880 --> 00:18:48,080
incorrect, especially when
it doesn't count, it

367
00:18:48,080 --> 00:18:49,860
doesn't hurt so bad.

368
00:18:49,860 --> 00:18:51,630
So, if you want to switch back
over to the notes, we'll

369
00:18:51,630 --> 00:18:56,770
explain why, in fact, the
correct answer is 4.

370
00:18:56,770 --> 00:19:00,580
So the key word here is that we
asked you to identify the

371
00:19:00,580 --> 00:19:02,280
third excited state.

372
00:19:02,280 --> 00:19:06,630
So, what white is n equal to for
the third excited state?

373
00:19:06,630 --> 00:19:07,910
4 OK.

374
00:19:07,910 --> 00:19:11,120
So that explains probably most
of the confusion here and you

375
00:19:11,120 --> 00:19:13,490
just want to be careful when
you're reading the problems

376
00:19:13,490 --> 00:19:15,640
that that's what you
read correctly.

377
00:19:15,640 --> 00:19:18,720
I think everyone would now get
the clicker question correct.

378
00:19:18,720 --> 00:19:23,160
So, the third excited state,
is n equal to 4, because n

379
00:19:23,160 --> 00:19:26,670
equals 2 is first excited, 3 is
second excited, 4 is third

380
00:19:26,670 --> 00:19:28,060
excited state.

381
00:19:28,060 --> 00:19:31,020
So now we can just take the
negative of that binding

382
00:19:31,020 --> 00:19:34,000
energy here, and I've just
rounded up here or 1 .

383
00:19:34,000 --> 00:19:37,690
4 times 10 to the negative
19 joules.

384
00:19:37,690 --> 00:19:41,220
So, I noticed that a few, a
very, very small proportion of

385
00:19:41,220 --> 00:19:43,530
you, did type in selections
that were

386
00:19:43,530 --> 00:19:45,650
negative ionization energies.

387
00:19:45,650 --> 00:19:48,650
And I'll just say it right now
you can absolutely never have

388
00:19:48,650 --> 00:19:50,660
a negative ionization energy,
so that's good

389
00:19:50,660 --> 00:19:52,180
to remember as well.

390
00:19:52,180 --> 00:19:54,240
And intuitively, it should make
sense, right, because

391
00:19:54,240 --> 00:19:56,690
ionization energy is the amount
of energy you need to

392
00:19:56,690 --> 00:20:00,060
put in to eject an electron
from an atom.

393
00:20:00,060 --> 00:20:02,290
So you don't want to put in a
negative energy, that's not

394
00:20:02,290 --> 00:20:05,010
going to help you out, you need
to put in positive energy

395
00:20:05,010 --> 00:20:07,520
to get an electron out
of the system.

396
00:20:07,520 --> 00:20:09,740
So that's why you'll find
binding energies are always

397
00:20:09,740 --> 00:20:12,300
negative, and ionization
energies are always going to

398
00:20:12,300 --> 00:20:15,040
be positive, or you could look
at the equation and see it

399
00:20:15,040 --> 00:20:17,810
from there as well.

400
00:20:17,810 --> 00:20:18,240
All right.

401
00:20:18,240 --> 00:20:21,440
So, using the equation we'd
initially discussed, the

402
00:20:21,440 --> 00:20:26,010
negative r sub h over n squared,
we could figure out

403
00:20:26,010 --> 00:20:28,610
all of the different ionization
energies and

404
00:20:28,610 --> 00:20:31,320
binding energies for a hydrogen
atom, and it turns

405
00:20:31,320 --> 00:20:35,050
out if we change the equation
only slightly to add a

406
00:20:35,050 --> 00:20:38,310
negative z squared in there, so,
negative z squared times

407
00:20:38,310 --> 00:20:41,570
the Rydberg constant over
n squared, now let's us

408
00:20:41,570 --> 00:20:46,250
calculate energy levels for
absolutely any atom as long as

409
00:20:46,250 --> 00:20:48,600
this one important stipulation,
it only has 1

410
00:20:48,600 --> 00:20:50,080
electron in it.

411
00:20:50,080 --> 00:20:52,540
So basically we're dealing with
hydrogen atoms and then

412
00:20:52,540 --> 00:20:55,240
we're going to be dealing
with ions.

413
00:20:55,240 --> 00:20:58,690
So, for example, a helium
plus 1 ion has 1

414
00:20:58,690 --> 00:21:01,250
electron at z equal 2.

415
00:21:01,250 --> 00:21:06,160
A lithium 2 plus ion has 1
electron, it has z equals 3,

416
00:21:06,160 --> 00:21:08,790
so if we were to plug in, we
would just do z squared up

417
00:21:08,790 --> 00:21:11,020
here, or 3 squared.

418
00:21:11,020 --> 00:21:14,610
Terbium 64 plus, another
1 electron atom.

419
00:21:14,610 --> 00:21:17,070
What is z for that?

420
00:21:17,070 --> 00:21:17,430
Yup.

421
00:21:17,430 --> 00:21:19,260
65.

422
00:21:19,260 --> 00:21:23,490
So again, terbium 64 plus, not
an ion we probably will run

423
00:21:23,490 --> 00:21:27,580
into, but if we did, we could,
in fact, calculate all of the

424
00:21:27,580 --> 00:21:31,030
energy levels for it using
this equation here.

425
00:21:31,030 --> 00:21:33,330
And the difference between the
equation, the reason that that

426
00:21:33,330 --> 00:21:37,500
z squared comes in there is
because if you go back to your

427
00:21:37,500 --> 00:21:40,650
notes from Wednesday, and you
look at the long written out

428
00:21:40,650 --> 00:21:43,600
form of the Schrodinger equation
for a hydrogen atom,

429
00:21:43,600 --> 00:21:47,250
or any 1 electron atom, you see
the last term there is a

430
00:21:47,250 --> 00:21:50,010
coulomb potential energy
between the

431
00:21:50,010 --> 00:21:51,960
electron and the nucleus.

432
00:21:51,960 --> 00:21:55,120
So, of course, when we have a
charge on the nucleus equal to

433
00:21:55,120 --> 00:21:58,585
1, as we do in a hydrogen atom,
the z is equal to 1, so

434
00:21:58,585 --> 00:22:01,240
it drops out there, but normally
we would have to

435
00:22:01,240 --> 00:22:04,390
include the full charge on the
nucleus, which is equal to z

436
00:22:04,390 --> 00:22:06,940
or the atomic number
times the electron.

437
00:22:06,940 --> 00:22:09,780
So even if we strip an atom of
all of its electrons, we still

438
00:22:09,780 --> 00:22:11,660
have that same amount
of positive

439
00:22:11,660 --> 00:22:13,680
charge in the nucleus.

440
00:22:13,680 --> 00:22:17,500
So, this allows us to look at a
bunch of different atoms, of

441
00:22:17,500 --> 00:22:20,230
course, limited to the fact
that it has to be

442
00:22:20,230 --> 00:22:23,790
a 1 electron atom.

443
00:22:23,790 --> 00:22:27,630
So, now that we can calculate
the binding energies, we can

444
00:22:27,630 --> 00:22:31,600
think about is this, in fact,
what matches up with what's

445
00:22:31,600 --> 00:22:34,280
been observed, or, in fact,
could we predict what we will

446
00:22:34,280 --> 00:22:36,800
observe in different kinds of
situations now that we know

447
00:22:36,800 --> 00:22:39,820
how to use the binding
energy, and hopefully

448
00:22:39,820 --> 00:22:42,100
we can and we will.

449
00:22:42,100 --> 00:22:46,510
So one thing we could do is we
could look at the different

450
00:22:46,510 --> 00:22:50,080
wavelengths of light that are
emitted by hydrogen atoms that

451
00:22:50,080 --> 00:22:51,820
are excited to a higher state.

452
00:22:51,820 --> 00:22:55,130
So what we'll do in a
few minutes here is

453
00:22:55,130 --> 00:22:56,650
try this with hydrogen.

454
00:22:56,650 --> 00:23:02,740
So we'll take h 2 and we'll run
-- or actually we'll have

455
00:23:02,740 --> 00:23:05,880
h 2 filled in an evacuated
glass tube.

456
00:23:05,880 --> 00:23:09,190
When we increase the potential
between the 2 electrodes that

457
00:23:09,190 --> 00:23:12,430
we have in the tube -- we
actually split the h 2 into

458
00:23:12,430 --> 00:23:16,200
the individual hydrogen atoms,
and not only do that, but also

459
00:23:16,200 --> 00:23:17,600
excite the atoms.

460
00:23:17,600 --> 00:23:20,590
So when you just run across an
atom in the street, you can

461
00:23:20,590 --> 00:23:22,910
assume it's going to be in its
most stable ground state,

462
00:23:22,910 --> 00:23:25,290
that's where the electron would
be, but when we add

463
00:23:25,290 --> 00:23:28,060
energy to the system, we can
actually excite it up into all

464
00:23:28,060 --> 00:23:31,110
different sorts of higher states
-- n equals 6, n equals

465
00:23:31,110 --> 00:23:33,740
10, any of those
higher states.

466
00:23:33,740 --> 00:23:36,210
But that only happens
momentarily, because, of

467
00:23:36,210 --> 00:23:39,080
course, if you have an energy in
a higher energy level, it's

468
00:23:39,080 --> 00:23:41,890
going to want to drop back down
to that lower or more

469
00:23:41,890 --> 00:23:42,890
stable level.

470
00:23:42,890 --> 00:23:46,050
And when it does that it's going
to give off some energy

471
00:23:46,050 --> 00:23:48,940
equal to the difference between
those two levels.

472
00:23:48,940 --> 00:23:52,000
And that will be associated
with a wavelength if it

473
00:23:52,000 --> 00:23:54,210
releases the energy in
terms of a photon.

474
00:23:54,210 --> 00:23:56,260
So that's what we'll look
at in a few minutes.

475
00:23:56,260 --> 00:23:59,000
There's some important things
to point out about what is

476
00:23:59,000 --> 00:24:00,260
happening here.

477
00:24:00,260 --> 00:24:03,000
Just to visualize exactly what
we're saying, what we're

478
00:24:03,000 --> 00:24:06,280
saying is when we have an energy
in a higher energy

479
00:24:06,280 --> 00:24:10,130
level, so let's say energy
level, this initial level high

480
00:24:10,130 --> 00:24:14,500
up here, and it drops down to
a lower final level, what we

481
00:24:14,500 --> 00:24:17,840
find is that the photon that
is going to be emitted is

482
00:24:17,840 --> 00:24:21,960
going to be emitted with the
exact energy, and the

483
00:24:21,960 --> 00:24:24,230
important term here
is the exact.

484
00:24:24,230 --> 00:24:29,050
That is the difference between
these two energy states.

485
00:24:29,050 --> 00:24:32,120
That makes sense because we're
losing energy, we're going to

486
00:24:32,120 --> 00:24:34,940
a level lower level, so we can
give off that extra in the

487
00:24:34,940 --> 00:24:36,630
form of light.

488
00:24:36,630 --> 00:24:38,780
And we can actually write the
equation for what we would

489
00:24:38,780 --> 00:24:40,980
expect the energy for
the light to be.

490
00:24:40,980 --> 00:24:44,660
So this delta energy here is
very simply the energy of the

491
00:24:44,660 --> 00:24:49,560
initial state minus the energy
of the final state.

492
00:24:49,560 --> 00:24:52,470
This is a little bit generic,
we're not actually specifying

493
00:24:52,470 --> 00:24:55,240
the states here, but we could,
we know we can calculate the

494
00:24:55,240 --> 00:24:57,020
energy from any of the states.

495
00:24:57,020 --> 00:25:00,740
So, for example, let's say we
excited the hydrogen atom such

496
00:25:00,740 --> 00:25:04,790
that the electron was starting
in the n equals 6 state, so

497
00:25:04,790 --> 00:25:06,130
that's our n initial.

498
00:25:06,130 --> 00:25:09,760
And we drop down to the n equals
2 state, or the first

499
00:25:09,760 --> 00:25:11,250
excited state.

500
00:25:11,250 --> 00:25:14,080
Then we would be able to change
our equation to make it

501
00:25:14,080 --> 00:25:17,810
a little bit more specific and
say that delta energy here is

502
00:25:17,810 --> 00:25:22,200
equal to energy of n equals 6,
minus the energy of the n

503
00:25:22,200 --> 00:25:24,860
equals 2 state.

504
00:25:24,860 --> 00:25:28,060
When we talk about that
frequency of light that's

505
00:25:28,060 --> 00:25:30,590
going to be emitted, it's not
too commonly that we'll

506
00:25:30,590 --> 00:25:32,700
actually talk about it
in terms of energy.

507
00:25:32,700 --> 00:25:35,450
A lot of times we talk about
light in terms of its

508
00:25:35,450 --> 00:25:39,260
frequency or it's wavelength,
but that's OK, because we know

509
00:25:39,260 --> 00:25:42,840
how to convert from energy to
frequency, so we can do that

510
00:25:42,840 --> 00:25:46,700
here as well, where our
frequency is just our energy

511
00:25:46,700 --> 00:25:49,610
divided by Planck's constant,
and since here we're talking

512
00:25:49,610 --> 00:25:52,300
about a delta energy, we're
going to talk about the

513
00:25:52,300 --> 00:25:56,690
frequency as being equal
to delta energy over h.

514
00:25:56,690 --> 00:25:59,760
Or we can say the frequency is
going to be equal to the

515
00:25:59,760 --> 00:26:02,350
energy initial minus the
energy final all

516
00:26:02,350 --> 00:26:05,090
over Planck's constant.

517
00:26:05,090 --> 00:26:07,660
So this means that we can go
directly from the energy

518
00:26:07,660 --> 00:26:10,880
between two levels to the
frequency of the photon that's

519
00:26:10,880 --> 00:26:14,230
emitted when you go between
those levels.

520
00:26:14,230 --> 00:26:17,590
What we can also do is say
something about the wavelength

521
00:26:17,590 --> 00:26:20,150
as well because we know the
relationship between energy

522
00:26:20,150 --> 00:26:22,640
and frequency and wavelength.

523
00:26:22,640 --> 00:26:25,300
So, in the first case here,
let's say we go from a high

524
00:26:25,300 --> 00:26:29,340
level to a low level, let's say
we go from five to one.

525
00:26:29,340 --> 00:26:32,660
If we have a large energy
difference here, are we going

526
00:26:32,660 --> 00:26:36,530
to have a high or
low frequency?

527
00:26:36,530 --> 00:26:36,920
Good.

528
00:26:36,920 --> 00:26:38,360
A high frequency.

529
00:26:38,360 --> 00:26:40,830
If we have a high frequency,
what about the wavelength,

530
00:26:40,830 --> 00:26:43,380
long or short?

531
00:26:43,380 --> 00:26:43,720
All right.

532
00:26:43,720 --> 00:26:44,080
Good.

533
00:26:44,080 --> 00:26:45,780
So we should always be
able to keep these

534
00:26:45,780 --> 00:26:47,390
relationships in mind.

535
00:26:47,390 --> 00:26:50,550
So, similarly in a case where
instead we have a small energy

536
00:26:50,550 --> 00:26:54,360
difference, we're going to have
a low frequency, which

537
00:26:54,360 --> 00:27:01,410
means that we're going to have
a long wavelength here.

538
00:27:01,410 --> 00:27:04,600
So now we can go ahead
and try observing

539
00:27:04,600 --> 00:27:06,140
some of this ourselves.

540
00:27:06,140 --> 00:27:09,870
So what we're actually going to
do is this experiment that

541
00:27:09,870 --> 00:27:13,760
I explained here where we're
going to excite hydrogen atoms

542
00:27:13,760 --> 00:27:17,040
such that they're electrons go
into these higher energy

543
00:27:17,040 --> 00:27:20,340
levels, and then we're going to
see if we can actually see

544
00:27:20,340 --> 00:27:23,610
individual wavelengths that
come out of that that

545
00:27:23,610 --> 00:27:25,840
correspond with the
energy difference.

546
00:27:25,840 --> 00:27:30,330
So, our detection devices are
a little bit limited here

547
00:27:30,330 --> 00:27:33,420
today, we're actually only going
to be using our eyes, so

548
00:27:33,420 --> 00:27:36,120
that means that we need to stick
with the visible range

549
00:27:36,120 --> 00:27:38,080
of the electromagnetic
spectrum.

550
00:27:38,080 --> 00:27:40,200
Actually that simplifies things,
because that really

551
00:27:40,200 --> 00:27:42,435
cuts down on the number of
wavelengths that we're going

552
00:27:42,435 --> 00:27:44,300
to be trying to observe here.

553
00:27:44,300 --> 00:27:47,770
So it turns out that in the
visible range, when you figure

554
00:27:47,770 --> 00:27:50,520
out the differences between
energy levels, in hydrogen

555
00:27:50,520 --> 00:27:53,470
atoms, there's only 4
wavelengths that fall in the

556
00:27:53,470 --> 00:27:55,080
visible range of the spectrum.

557
00:27:55,080 --> 00:27:58,120
So hopefully, when we turn out
the lights, we're going to

558
00:27:58,120 --> 00:28:03,320
turn on this lamp here, which
has hydrogen in it and we're

559
00:28:03,320 --> 00:28:05,140
going to excite that hydrogen.

560
00:28:05,140 --> 00:28:08,280
You'll see light coming out, but
it's, of course, going to

561
00:28:08,280 --> 00:28:11,060
be bulk light -- you're not
going to be able to tell the

562
00:28:11,060 --> 00:28:12,220
individual wavelengths.

563
00:28:12,220 --> 00:28:15,150
So what our TAs, actually if
they can come down now, are

564
00:28:15,150 --> 00:28:19,360
going to pass out to you is
these either defraction

565
00:28:19,360 --> 00:28:23,230
goggles, or just a little plate,
and you're going to be

566
00:28:23,230 --> 00:28:26,870
splitting that light into its
individual wavelengths.

567
00:28:26,870 --> 00:28:30,960
And the glasses, there aren't
enough to go around for all of

568
00:28:30,960 --> 00:28:32,460
you, so that's why
there's plates.

569
00:28:32,460 --> 00:28:35,070
And though glasses do look way
cooler, the plates work a

570
00:28:35,070 --> 00:28:37,470
little better, so either you or
your neighbor should try to

571
00:28:37,470 --> 00:28:39,070
have one of the plates
in case one of you

572
00:28:39,070 --> 00:28:40,300
can't see all the lines.

573
00:28:40,300 --> 00:28:49,920
So our TAs will pass these
around for us.

574
00:28:49,920 --> 00:28:53,390
And I also want to point out,
it's guaranteed pretty much

575
00:28:53,390 --> 00:28:56,040
you'll be able to see these
three here in the visible

576
00:28:56,040 --> 00:28:58,860
range -- you may or may not be
able to see, sometimes it's

577
00:28:58,860 --> 00:29:03,550
hard to see that one that's
getting near the UV end of our

578
00:29:03,550 --> 00:29:04,550
visible spectrum.

579
00:29:04,550 --> 00:29:14,490
So we won't worry if
we can't see that.

580
00:29:14,490 --> 00:29:24,590
I'll take one actually.

581
00:29:24,590 --> 00:29:53,330
Can you raise your hand if you
if you still need one?

582
00:29:53,330 --> 00:29:56,350
All right, so TA's walk
carefully now, I'm going to

583
00:29:56,350 --> 00:29:58,210
shut the lights down here.

584
00:29:58,210 --> 00:30:10,140
All right, so we do still have
some little bits of ambient

585
00:30:10,140 --> 00:30:12,360
light, so you might
see a slight

586
00:30:12,360 --> 00:30:14,290
amount of the full continuum.

587
00:30:14,290 --> 00:30:17,370
But if you look through your
plate, and actually especially

588
00:30:17,370 --> 00:30:20,810
if you kind of look off to the
side, hopefully you'll be able

589
00:30:20,810 --> 00:30:25,240
to see the individual lines
of the spectrum.

590
00:30:25,240 --> 00:30:27,480
Is everyone seeing that?

591
00:30:27,480 --> 00:30:28,390
Yeah, pretty much.

592
00:30:28,390 --> 00:30:29,730
OK.

593
00:30:29,730 --> 00:30:30,880
Can anyone not see it?

594
00:30:30,880 --> 00:30:32,850
Does anyone need -- actually
I can't even tell if

595
00:30:32,850 --> 00:30:33,480
you raise your hand.

596
00:30:33,480 --> 00:30:36,380
So ask your neighbor if you
can't see it and get one of

597
00:30:36,380 --> 00:30:37,680
the plates if you're
having trouble

598
00:30:37,680 --> 00:30:39,470
seeing with the glasses.

599
00:30:39,470 --> 00:30:42,980
So this should match up with
the spectrum that we saw.

600
00:30:42,980 --> 00:30:46,380
And actually keep those
glasses with you.

601
00:30:46,380 --> 00:30:49,710
We'll turn the light back
on for a second here.

602
00:30:49,710 --> 00:30:53,400
And hydrogen atom is what
we're learning about, so

603
00:30:53,400 --> 00:30:54,740
that's the most relevant here.

604
00:30:54,740 --> 00:30:58,580
But just to show you that each
atom does have its own set of

605
00:30:58,580 --> 00:31:02,990
spectral lines, just for fun
we'll look at neon also so you

606
00:31:02,990 --> 00:31:17,280
can have a comparison point.

607
00:31:17,280 --> 00:31:17,690
All right.

608
00:31:17,690 --> 00:31:20,320
So, this is probably a familiar
color having seen

609
00:31:20,320 --> 00:31:28,720
many neon lights around
everywhere.

610
00:31:28,720 --> 00:31:31,780
So you see with the neon is
there's just a lot more lines

611
00:31:31,780 --> 00:31:35,700
in that orange part of the
spectrum then compared to the

612
00:31:35,700 --> 00:31:39,980
hydrogen, and that's really what
gives you that neon color

613
00:31:39,980 --> 00:31:41,480
in the neon signs.

614
00:31:41,480 --> 00:31:45,160
That's the true color of a neon
being excited, sometimes

615
00:31:45,160 --> 00:31:49,060
neon signs are painted
with other compounds.

616
00:31:49,060 --> 00:31:50,970
All right, does everyone
have their fill of

617
00:31:50,970 --> 00:31:51,890
seeing the neon lines?

618
00:31:51,890 --> 00:31:53,950
STUDENT: No.

619
00:31:53,950 --> 00:31:56,490
PROFESSOR: All right, let's take
two more seconds to look

620
00:31:56,490 --> 00:32:01,920
at neon then.

621
00:32:01,920 --> 00:32:02,350
All right.

622
00:32:02,350 --> 00:32:08,350
So our special effects portion
of the class is over.

623
00:32:08,350 --> 00:32:10,850
And what you see when we see it
with our eye, which is all

624
00:32:10,850 --> 00:32:13,580
the wavelengths, of course,
mixed together, is whichever

625
00:32:13,580 --> 00:32:15,900
those wavelengths
is most intense.

626
00:32:15,900 --> 00:32:18,290
So, when we looked at the
individual neon lines, it was

627
00:32:18,290 --> 00:32:21,560
the orange colors that was most
intense, which is why we

628
00:32:21,560 --> 00:32:25,330
were seeing kind of a general
orange glow with the neon,

629
00:32:25,330 --> 00:32:29,290
which is different from what
we see with the hydrogen.

630
00:32:29,290 --> 00:32:35,400
All right, so we can, in fact,
observe individual lines.

631
00:32:35,400 --> 00:32:37,860
There's nothing more exciting
to see with your glasses on,

632
00:32:37,860 --> 00:32:38,590
while you look nice.

633
00:32:38,590 --> 00:32:42,690
You can take those off if you
wish to, or you can try to

634
00:32:42,690 --> 00:32:46,490
just be splitting the light in
the room until the TAs grab

635
00:32:46,490 --> 00:32:48,360
your glasses, either is fine.

636
00:32:48,360 --> 00:32:51,130
It turns out that we are far
from the first people,

637
00:32:51,130 --> 00:32:53,950
although it felt exciting, we
did not discover this for the

638
00:32:53,950 --> 00:32:56,570
first time here today.

639
00:32:56,570 --> 00:33:01,930
In fact, J.J. Balmer, who was a
school teacher in the 1800s,

640
00:33:01,930 --> 00:33:05,810
was the first to describe these
lines that could be seen

641
00:33:05,810 --> 00:33:07,130
from hydrogen.

642
00:33:07,130 --> 00:33:11,060
And he saw the same lines that
we saw here today, and

643
00:33:11,060 --> 00:33:16,200
although he could not explain,
even start to explain why you

644
00:33:16,200 --> 00:33:19,090
saw only these specific
lines and not a whole

645
00:33:19,090 --> 00:33:20,310
continuum of the light.

646
00:33:20,310 --> 00:33:22,600
Right, we already have an idea
because we just talked about

647
00:33:22,600 --> 00:33:24,860
energy levels, we know there's
only certain allowed energy

648
00:33:24,860 --> 00:33:27,540
levels, but at the time there's
no reason J.J. Balmer

649
00:33:27,540 --> 00:33:30,410
should have known this, and in
fact he didn't, but he still

650
00:33:30,410 --> 00:33:33,750
came up with a quantitative
way to describe

651
00:33:33,750 --> 00:33:34,920
what was going on.

652
00:33:34,920 --> 00:33:38,720
He came up with this equation
here where what he found was

653
00:33:38,720 --> 00:33:42,180
that he could explain the
wavelengths of these different

654
00:33:42,180 --> 00:33:48,040
lines by multiplying 1 over 4
minus 1 over some integer n,

655
00:33:48,040 --> 00:33:51,140
and multiplying it by
this number, 3 .

656
00:33:51,140 --> 00:33:55,300
29 times 10 to the 15 Hertz,
and he found that this was

657
00:33:55,300 --> 00:33:57,510
true where n was some
integer value --

658
00:33:57,510 --> 00:34:00,900
3, 4, 5, or 6.

659
00:34:00,900 --> 00:34:11,990
So he could explain it
quantitatively in terms of

660
00:34:11,990 --> 00:34:14,100
putting an equation with it, but
he couldn't explain what

661
00:34:14,100 --> 00:34:15,780
was actually going on.

662
00:34:15,780 --> 00:34:19,310
But we, having learned about
energy levels, having had the

663
00:34:19,310 --> 00:34:22,670
Schrodinger equation solved for
us to understand what's

664
00:34:22,670 --> 00:34:26,420
going on, can, in fact, explain
what happened when we

665
00:34:26,420 --> 00:34:28,420
saw these different colors.

666
00:34:28,420 --> 00:34:30,440
So, what we know is happening
is that were having

667
00:34:30,440 --> 00:34:36,590
transitions from some excited
states to a more relaxed

668
00:34:36,590 --> 00:34:39,360
lower, more stable state
in the hydrogen atom.

669
00:34:39,360 --> 00:34:43,630
And it turns out what we can
detect visibly with our eyes

670
00:34:43,630 --> 00:34:46,930
is in the visible range, and
that means that the final

671
00:34:46,930 --> 00:34:49,630
state is n equals 2.

672
00:34:49,630 --> 00:34:52,830
Because you see how n equals 1
is so much further away, and

673
00:34:52,830 --> 00:34:55,060
actually that's not to scale,
it's actually much, much

674
00:34:55,060 --> 00:34:58,570
further down in the energy well,
such that the energy of

675
00:34:58,570 --> 00:35:01,500
the light is so great that
it's going to be in

676
00:35:01,500 --> 00:35:04,630
ultraviolet very high energy,
high frequency range.

677
00:35:04,630 --> 00:35:07,600
So we can't actually see any of
that, it's too high energy

678
00:35:07,600 --> 00:35:08,560
for us to see.

679
00:35:08,560 --> 00:35:11,940
So everything we see is going to
be where we have the final

680
00:35:11,940 --> 00:35:15,210
energy state being n equals 2.

681
00:35:15,210 --> 00:35:19,310
So if we think about, for
example, this red line here,

682
00:35:19,310 --> 00:35:23,980
which energy state or which
principle quantum number do

683
00:35:23,980 --> 00:35:30,450
you think that our electron
started in?

684
00:35:30,450 --> 00:35:30,910
STUDENT: Three.

685
00:35:30,910 --> 00:35:31,230
PROFESSOR: Good.

686
00:35:31,230 --> 00:35:33,540
So, it's going to be in 3,
because that's the shortest

687
00:35:33,540 --> 00:35:37,960
energy difference we can have,
and the red is the longest

688
00:35:37,960 --> 00:35:40,960
wavelength we can see -- those 2
are inversely related, so it

689
00:35:40,960 --> 00:35:42,960
must be n equals 3.

690
00:35:42,960 --> 00:35:47,640
What about the kind of cyan-ish,
blue-green one?

691
00:35:47,640 --> 00:35:50,440
Yup. so n equals
4 for that one.

692
00:35:50,440 --> 00:35:53,240
Similarly we can go on,
match up the others.

693
00:35:53,240 --> 00:35:56,630
So n equals 5 for the
bluish-purple and the violet

694
00:35:56,630 --> 00:35:58,250
is n equals 6.

695
00:35:58,250 --> 00:36:01,230
And again, that matches up,
because the violet, or getting

696
00:36:01,230 --> 00:36:05,750
really close to the UV range
here has the longest energy,

697
00:36:05,750 --> 00:36:08,510
so the highest frequency, and
that's going to be the

698
00:36:08,510 --> 00:36:11,170
shortest wavelength and we can
see here it is, in fact, the

699
00:36:11,170 --> 00:36:15,470
shortest wavelength that
we can actually see.

700
00:36:15,470 --> 00:36:19,670
So, we can see if we can come up
with the same equation that

701
00:36:19,670 --> 00:36:23,700
J.J. Balmer came up with by
actually starting with what we

702
00:36:23,700 --> 00:36:26,830
know and working our way that
way instead of coming up from

703
00:36:26,830 --> 00:36:29,880
the other direction, which he
did, which was just to explain

704
00:36:29,880 --> 00:36:31,070
what he saw.

705
00:36:31,070 --> 00:36:33,830
So, if we start instead with
talking about the energy

706
00:36:33,830 --> 00:36:36,850
levels, we can relate these to
frequency, because we already

707
00:36:36,850 --> 00:36:40,050
said that frequency is related
to, or it's equal to the

708
00:36:40,050 --> 00:36:43,840
initial energy level here minus
the final energy level

709
00:36:43,840 --> 00:36:47,540
there over Planck's constant
to get us to frequency.

710
00:36:47,540 --> 00:36:51,480
And we also have the equation
that comes out of Schrodinger

711
00:36:51,480 --> 00:36:55,420
equation that tell us exactly
what that binding energy is,

712
00:36:55,420 --> 00:36:57,260
that binding energy is just
equal to the negative of the

713
00:36:57,260 --> 00:37:01,800
Rydberg constant
over n squared.

714
00:37:01,800 --> 00:37:05,060
So that means that our frequency
is going to equal,

715
00:37:05,060 --> 00:37:10,250
if we plug in e n into the
initial and final energy here,

716
00:37:10,250 --> 00:37:14,690
1 over Planck's constant times
negative r h over n initial

717
00:37:14,690 --> 00:37:19,890
squared, minus negative r
h over n final squared.

718
00:37:19,890 --> 00:37:22,990
So we have an equation that
should relate how we can

719
00:37:22,990 --> 00:37:26,630
actually calculate
the frequency to

720
00:37:26,630 --> 00:37:29,180
what J.J. Balmer observed.

721
00:37:29,180 --> 00:37:32,055
We can simplify this equation
by pulling up the r h and

722
00:37:32,055 --> 00:37:35,450
getting rid of some of these
negatives here by saying the

723
00:37:35,450 --> 00:37:38,560
frequency is going to be equal
to the Rydberg constant

724
00:37:38,560 --> 00:37:43,120
divided by Planck's constant
all times 1 over n final

725
00:37:43,120 --> 00:37:46,120
squared -- this is just to
switch the signs around and

726
00:37:46,120 --> 00:37:48,460
get rid of some negatives
-- minus 1

727
00:37:48,460 --> 00:37:53,130
over n initial squared.

728
00:37:53,130 --> 00:37:56,760
We can plug this in further when
we're talking about the

729
00:37:56,760 --> 00:38:00,170
visible part of the light
spectrum, because we know that

730
00:38:00,170 --> 00:38:04,160
for n final equals 2, then that
would mean we plug in 2

731
00:38:04,160 --> 00:38:06,940
squared here, so what
we get is 1 over 4.

732
00:38:06,940 --> 00:38:10,570
So this is our final equation,
and this is actually called

733
00:38:10,570 --> 00:38:13,590
the Balmer series, which was
named after Balmer, and this

734
00:38:13,590 --> 00:38:18,010
tells us the frequency of any
of the lights where we start

735
00:38:18,010 --> 00:38:20,490
with an electron in some higher
energy level and we

736
00:38:20,490 --> 00:38:23,300
drop down to an n final
that's equal to 2.

737
00:38:23,300 --> 00:38:25,690
So it's a more specific version
of the equation where

738
00:38:25,690 --> 00:38:28,980
we have the n final
equal to 2.

739
00:38:28,980 --> 00:38:31,930
And it turns out that actually
we find that this matches up

740
00:38:31,930 --> 00:38:36,420
perfectly with Balmer's
equation, because the value of

741
00:38:36,420 --> 00:38:39,460
r h, the Rydberg constant
divided by the Planck's

742
00:38:39,460 --> 00:38:42,950
constant is actually -- it's
also another constant, so we

743
00:38:42,950 --> 00:38:44,370
can write it as this
kind of strange

744
00:38:44,370 --> 00:38:46,430
looking cursive r here.

745
00:38:46,430 --> 00:38:49,630
Unfortunately, this is also call
the Rydberg constant, so

746
00:38:49,630 --> 00:38:50,800
it's a little bit confusing.

747
00:38:50,800 --> 00:38:55,560
But really it means the Rydberg
constant divided by h,

748
00:38:55,560 --> 00:38:57,250
and that's equal to 3 .

749
00:38:57,250 --> 00:38:59,970
29 times 10 to the
15 per second.

750
00:38:59,970 --> 00:39:04,140
So if you remember what the
equation Balmer found was this

751
00:39:04,140 --> 00:39:06,470
number multiplied
by this here.

752
00:39:06,470 --> 00:39:09,830
So, we found the exact same
equation, but just now

753
00:39:09,830 --> 00:39:11,730
starting from understanding
the difference

754
00:39:11,730 --> 00:39:14,000
between energy levels.

755
00:39:14,000 --> 00:39:17,740
So, sometimes you'll find the
Rydberg constant in different

756
00:39:17,740 --> 00:39:21,010
forms, but just make sure you
pay attention to units because

757
00:39:21,010 --> 00:39:23,350
then you won't mess them up,
because this is in inverse

758
00:39:23,350 --> 00:39:26,230
seconds here, the other Rydberg
constant is in joules,

759
00:39:26,230 --> 00:39:29,470
so you'll be able to use what
you need depending on how

760
00:39:29,470 --> 00:39:33,230
you're using that constant.

761
00:39:33,230 --> 00:39:37,570
So in talking about the hydrogen
atom, they actually

762
00:39:37,570 --> 00:39:42,440
have different names for
different series, which means

763
00:39:42,440 --> 00:39:46,000
in terms of different n
values that we end in.

764
00:39:46,000 --> 00:39:48,930
So we talked about what we could
see with visible light,

765
00:39:48,930 --> 00:39:51,250
we said that's actually
the Balmer series.

766
00:39:51,250 --> 00:39:54,750
So anything that goes from a
higher energy level to 2 is

767
00:39:54,750 --> 00:39:57,960
going to be falling within the
Balmer series, which is in the

768
00:39:57,960 --> 00:40:00,610
visible range of the spectrum.

769
00:40:00,610 --> 00:40:03,830
We can think about the Lyman
series, which is

770
00:40:03,830 --> 00:40:05,280
where n equals 1.

771
00:40:05,280 --> 00:40:08,570
We know that that's going to be
a higher energy difference,

772
00:40:08,570 --> 00:40:12,660
so that means that we're going
to be in the UV range.

773
00:40:12,660 --> 00:40:15,140
We can also go in the
opposite direction.

774
00:40:15,140 --> 00:40:18,690
So, for example, when n equals
3, that's called the Paschen

775
00:40:18,690 --> 00:40:21,430
series, and these are named
after basically the people

776
00:40:21,430 --> 00:40:24,650
that first discovered these
different lines and

777
00:40:24,650 --> 00:40:27,790
characterized them, and this
is in the near IR range.

778
00:40:27,790 --> 00:40:31,680
And again, the n equals 4 is
the Brackett series, and

779
00:40:31,680 --> 00:40:33,270
that's an IR range.

780
00:40:33,270 --> 00:40:36,530
I think there's names for even
a few more levels up.

781
00:40:36,530 --> 00:40:39,370
You don't need to know those,
but just because it's a

782
00:40:39,370 --> 00:40:41,880
special case with the hydrogen
atom, they do tend to be named

783
00:40:41,880 --> 00:40:44,970
-- the most important, of
course, tends to be the Balmer

784
00:40:44,970 --> 00:40:47,670
series because that's what we
can actually see being emitted

785
00:40:47,670 --> 00:40:51,060
from the hydrogen atom.

786
00:40:51,060 --> 00:40:55,900
So, now we should be able to
relate what we know about

787
00:40:55,900 --> 00:41:00,220
different frequencies and
different wavelengths, so

788
00:41:00,220 --> 00:41:06,190
Darcy can you switch us over
to a clicker question here?

789
00:41:06,190 --> 00:41:09,940
And we can also talk about the
difference between what's

790
00:41:09,940 --> 00:41:13,110
happening when we have emission,
and we're going to

791
00:41:13,110 --> 00:41:14,190
switch over to absorption.

792
00:41:14,190 --> 00:41:17,850
So, we just talked about
emission, so before we head

793
00:41:17,850 --> 00:41:20,360
into absorption, if you can
answer this clicker question

794
00:41:20,360 --> 00:41:23,580
in terms of what do you think
absorption means having just

795
00:41:23,580 --> 00:41:27,610
discussed hydrogen
emission here?

796
00:41:27,610 --> 00:41:31,030
So we have four choices in terms
of initial and final

797
00:41:31,030 --> 00:41:33,276
energy levels, and also what
it means in terms of the

798
00:41:33,276 --> 00:41:36,320
electron -- whether it's gaining
energy or whether it's

799
00:41:36,320 --> 00:41:39,940
going to be emitting energy?

800
00:41:39,940 --> 00:41:42,440
So, why do you take 10 seconds
on that, we'll

801
00:41:42,440 --> 00:41:54,500
make it a quick one.

802
00:41:54,500 --> 00:41:55,100
All right, great.

803
00:41:55,100 --> 00:41:58,510
So already just from knowing
the emission part, we can

804
00:41:58,510 --> 00:42:00,470
figure out what absorption
probably means.

805
00:42:00,470 --> 00:42:03,590
Absorption is just the opposite
of emission, so

806
00:42:03,590 --> 00:42:10,220
instead of starting at a high
energy level and dropping

807
00:42:10,220 --> 00:42:13,800
down, when we absorb light we
start low and we absorb energy

808
00:42:13,800 --> 00:42:17,750
to bring ourselves up to an
n final that's higher.

809
00:42:17,750 --> 00:42:21,100
And instead of having the
electron giving off energy as

810
00:42:21,100 --> 00:42:23,920
a photon, instead now the
electron is going to take in

811
00:42:23,920 --> 00:42:29,800
energy from light and move
up to that higher level.

812
00:42:29,800 --> 00:42:32,390
So now we're going to be talking
briefly about photon

813
00:42:32,390 --> 00:42:33,780
absorption here.

814
00:42:33,780 --> 00:42:37,260
So again, this is just stating
the same thing, and it could

815
00:42:37,260 --> 00:42:40,880
take in a long wavelength light,
which would give it

816
00:42:40,880 --> 00:42:43,980
just a little bit of energy,
maybe just enough to head up

817
00:42:43,980 --> 00:42:48,550
one energy level or two, or we
could take in a high energy

818
00:42:48,550 --> 00:42:51,800
photon, and that means that the
electron is going to get

819
00:42:51,800 --> 00:42:56,690
to move up to an even
higher energy level.

820
00:42:56,690 --> 00:43:00,110
And again, we can talk about the
same relationship here, so

821
00:43:00,110 --> 00:43:02,670
it's a very similar equation to
the Rydberg equation that

822
00:43:02,670 --> 00:43:06,450
we saw earlier, except now what
you see is the n initial

823
00:43:06,450 --> 00:43:08,810
and the n final are
swapped places.

824
00:43:08,810 --> 00:43:12,620
So instead now we have r h over
Planck's constant times 1

825
00:43:12,620 --> 00:43:17,470
over n initial squared minus
n final squared.

826
00:43:17,470 --> 00:43:20,570
And what you want to keep in
mind is that whatever you're

827
00:43:20,570 --> 00:43:23,230
dealing with, whether it's
absorption or emission, the

828
00:43:23,230 --> 00:43:25,340
frequency of the light is always
going to be a positive

829
00:43:25,340 --> 00:43:27,760
number, so you always want to
make sure what's inside these

830
00:43:27,760 --> 00:43:29,780
brackets here turns out
to be positive.

831
00:43:29,780 --> 00:43:32,540
So that's just a little bit of
a check for yourself, and it

832
00:43:32,540 --> 00:43:36,080
should make sense because what
you're doing is you're

833
00:43:36,080 --> 00:43:39,160
calculating the difference
between energy levels, so you

834
00:43:39,160 --> 00:43:42,620
just need to flip around which
you put first to end up with a

835
00:43:42,620 --> 00:43:44,770
positive number here, and that's
a little bit of a check

836
00:43:44,770 --> 00:43:48,250
that you can do what yourself.

837
00:43:48,250 --> 00:43:51,300
So let's do a sample calculation
now using this

838
00:43:51,300 --> 00:43:55,050
Rydberg formula, and we'll
switch back to emission, and

839
00:43:55,050 --> 00:43:57,490
the reason that we'll do that is
because it would be nice to

840
00:43:57,490 --> 00:44:01,450
actually approve what we just
saw here and calculate the

841
00:44:01,450 --> 00:44:04,140
frequency of one of our lines
in the wavelength of one of

842
00:44:04,140 --> 00:44:05,850
the lines we saw.

843
00:44:05,850 --> 00:44:09,340
So what we'll do is this problem
here, which is let's

844
00:44:09,340 --> 00:44:11,870
calculate out what the
wavelength of radiation would

845
00:44:11,870 --> 00:44:16,520
be emitted from a hydrogen
atom if we start at the n

846
00:44:16,520 --> 00:44:22,750
equals 3 level and we go down
to the n equals 2 level.

847
00:44:22,750 --> 00:44:29,990
So what we need to do here is
use the Rydberg formula, and

848
00:44:29,990 --> 00:44:32,670
actually you'll be given the
Rydberg formulas in both

849
00:44:32,670 --> 00:44:37,530
forms, both or absorption and
emission on the exams. if you

850
00:44:37,530 --> 00:44:41,020
don't want to use that, you can
also derive it as we did

851
00:44:41,020 --> 00:44:42,950
every time, it should
intuitively make

852
00:44:42,950 --> 00:44:44,360
sense how we got there.

853
00:44:44,360 --> 00:44:47,010
But the exams are pretty short,
so we don't want you

854
00:44:47,010 --> 00:44:49,420
doing that every time, so we'll
save the 2 minutes and

855
00:44:49,420 --> 00:44:51,230
give you the equations directly,
but it's still

856
00:44:51,230 --> 00:44:53,980
important to know
how to use them.

857
00:44:53,980 --> 00:44:56,980
So, we can get from these
energy differences to

858
00:44:56,980 --> 00:45:02,730
frequency by frequency is equal
to r sub h over Planck's

859
00:45:02,730 --> 00:45:07,960
constant times 1 over n
final squared minus 1

860
00:45:07,960 --> 00:45:12,710
over n initial squared.

861
00:45:12,710 --> 00:45:16,090
So let's actually just simplify
this to the other

862
00:45:16,090 --> 00:45:17,970
version of the Rydberg
constant, since we

863
00:45:17,970 --> 00:45:19,300
can use that here.

864
00:45:19,300 --> 00:45:23,500
So kind of that strange cursive
r, and our n final is

865
00:45:23,500 --> 00:45:30,830
2, so 1 over 2 squared minus n
initial, so 1 over 3 squared.

866
00:45:30,830 --> 00:45:35,660
So, our frequency of light
is going to be equal to r

867
00:45:35,660 --> 00:45:40,980
times 5 over 36.

868
00:45:40,980 --> 00:45:43,790
But when we were actually
looking at our different

869
00:45:43,790 --> 00:45:46,630
wavelengths, what we associate
mostly with color is the wave

870
00:45:46,630 --> 00:45:49,770
length of the light and not the
frequency of the light, so

871
00:45:49,770 --> 00:45:52,110
let's look at wavelength
instead.

872
00:45:52,110 --> 00:45:57,100
We know that wavelength
is equal to c over nu.

873
00:45:57,100 --> 00:46:02,140
We can plug in what we have
for nu, so we have 36 c

874
00:46:02,140 --> 00:46:08,360
divided by 5, and that cursivey
Rydberg constant, and

875
00:46:08,360 --> 00:46:12,540
that gives us 36 times the
speed of light, 2 .

876
00:46:12,540 --> 00:46:23,500
998 times 10 the 8 meters per
second, all over 5 times 3 .

877
00:46:23,500 --> 00:46:31,400
29 times 10 to the
15 per second.

878
00:46:31,400 --> 00:46:34,570
So, what we end up getting when
we do this calculation is

879
00:46:34,570 --> 00:46:39,070
the wavelength of light,
which is equal to 6 .

880
00:46:39,070 --> 00:46:45,130
57 times 10 to the negative 7
meters, or if we convert that

881
00:46:45,130 --> 00:46:49,580
to nanometers, we have
657 nanometers.

882
00:46:49,580 --> 00:46:52,560
So does anyone remember what
range of light 657

883
00:46:52,560 --> 00:46:55,390
nanometers falls in?

884
00:46:55,390 --> 00:46:56,080
What color?

885
00:46:56,080 --> 00:46:57,370
STUDENT: Red.

886
00:46:57,370 --> 00:46:59,240
PROFESSOR: Yeah, it's
in the red range.

887
00:46:59,240 --> 00:47:00,430
So that's promising.

888
00:47:00,430 --> 00:47:05,050
We did, in fact, see red in our
spectrum, and it turns out

889
00:47:05,050 --> 00:47:07,970
that that's exactly the
wavelength that we see is that

890
00:47:07,970 --> 00:47:10,790
we're at 657 nanometers.

891
00:47:10,790 --> 00:47:15,330
So it turns out that we can, in
fact, use the energy levels

892
00:47:15,330 --> 00:47:18,290
to predict, and we could if we
wanted to do them for all of

893
00:47:18,290 --> 00:47:20,650
the different wavelengths of
light that we observed, and

894
00:47:20,650 --> 00:47:22,390
also all the different
wavelengths of light that can

895
00:47:22,390 --> 00:47:26,810
be detected, even if we
can't observe them.

896
00:47:26,810 --> 00:47:29,490
All right, so that's what we're
going to cover in terms

897
00:47:29,490 --> 00:47:32,290
of the energy portion of the
Schrodinger equation.

898
00:47:32,290 --> 00:47:36,400
I mentioned that we can also
solve for psi here, which is

899
00:47:36,400 --> 00:47:39,700
the wave function, and we're
running a little short on

900
00:47:39,700 --> 00:47:42,880
time, so we'll start on
Monday with solving

901
00:47:42,880 --> 00:47:44,670
for the wave function.