-
-
If I were to draw a hand, and
let me just draw a hand really
-
fast, so I'll draw
a left hand.
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It looks something like that.
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That is a left hand.
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Now, if I were to take its
mirror image, let's say that
-
this is a mirror right there,
and I want to take its mirror
-
image, and I'll draw the
mirror image in green.
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So its mirror image would look
something like this.
-
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Not exact, but you
get the idea.
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The mirror image of a left
hand looks a lot
-
like a right hand.
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Now, no matter how I try to
shift or rotate this hand like
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this, I might try to maybe
rotate it 180 degrees, so that
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the thumb is on the other side
like this image right here.
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But no matter what I do, I will
never be able to make
-
this thing look like
that thing.
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I can shift it and rotate it,
it'll just never happen.
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I will never be able to
superimpose the blue hand on
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top of this green hand.
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When I say superimpose,
literally put it exactly on
-
top of the green hand.
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So whenever something is not
superimposable on its mirror
-
image-- let me write this down--
we call it chiral.
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So this hand drawing
right here is an
-
example of a chiral object.
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Or I guess the hand is an
example of a chiral object.
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This is not superimposable
on its mirror image.
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And it makes sense that it's
called chiral because the word
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chiral comes from the
Greek word for hand.
-
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And this definition of
not being able to be
-
superimposable on its mirror
image, this applies whether
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you're dealing with chemistry,
or mathematics, or I guess,
-
just hands in general.
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So if we extend this definition
to chemistry,
-
because that's what we're
talking about, there's two
-
concepts here.
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There are chiral molecules,
and then there are chiral
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centers or chiral-- well, I call
them chiral atoms. They
-
tend to be carbon atoms, so
sometimes they call them
-
chiral carbons.
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So you have these
chiral atoms.
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Now, chiral molecules are
literally molecules that are
-
not superimposable on
their mirror image.
-
-
I'm not going to write
the whole thing.
-
You know, not superimposable--
I'll just
-
write the whole thing.
-
Not superimposable
on mirror image.
-
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Now, for chiral atoms, this is
essentially true, but when you
-
look for chiral atoms within a
molecule, the best way to spot
-
them is to recognize that these
generally, or maybe I
-
should say usually, are carbons,
especially when we're
-
dealing in organic chemistry,
but they could be phosphoruses
-
or sulfurs, but usually are
carbons bonded to four
-
different groups.
-
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And I want to emphasize
groups, not just four
-
different atoms. And to kind of
highlight a molecule that
-
contains a chiral atom or chiral
carbon, we can just
-
think of one.
-
So let's say that I have a
carbon right here, and I'm
-
going to set this up so this
is actually a chiral atom,
-
that the carbon specific is a
chiral atom, but it's partly a
-
chiral molecule.
-
And then we'll see examples
that one or both
-
of these are true.
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Let's say it's bonded
to a methyl group.
-
From that bond, it kind of
pops out of the page.
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Let's say there's a
bromine over here.
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Let's say behind it, there is a
hydrogen, and then above it,
-
we have a fluorine.
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Now if I were to take the mirror
image of this thing
-
right here, we have your carbon
in the center-- I want
-
to do it in that same blue.
-
You have the carbon in the
center and then you have the
-
fluorine above the carbon.
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You have your bromine now
going in this direction.
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You have this methyl group.
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It's still popping out of the
page, but it's now going to
-
the right instead of to
the left, So CH3.
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And then you have the hydrogen
still in the back.
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These are mirror images, if you
view this as kind of the
-
mirror and you can see on both
sides of the mirror.
-
Now, why is this chiral?
-
Well, it's a little bit of a
visualization challenge, but
-
no matter how you try to rotate
this thing right here,
-
you will never make it exactly
like this thing.
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You might try to rotate it
around like that and try to
-
get the methyl group over here,
to get it over there.
-
So let's try to do that.
-
If we try to get the methyl
group over there, what's going
-
to happen to the other groups?
-
Well, then the hydrogen group is
going-- or the hydrogen, I
-
should say.
-
The hydrogen atom is going to
move there and the bromine is
-
going to move there.
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So this would be superimposable
if this was a
-
hydrogen and this was a
bromine, but it's not.
-
You can imagine, the hydrogen
and bromine are switched.
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And you could flip it and do
whatever else you want or try
-
to rotate it in any direction,
but you're not going to be
-
able to superimpose them.
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So this molecule right here is
a chiral molecule, and this
-
carbon is a chiral center, so
this carbon is a chiral
-
carbon, sometimes called
an asymmetric
-
carbon or a chiral center.
-
Sometimes you'll hear
something called a
-
stereocenter.
-
A stereocenter is a more general
term for any point in
-
a molecule that is asymmetric
relative to the different
-
groups that it is joined to.
-
But all of these, especially
when you're in kind of in
-
introductory organic chemistry
class, tends to be a carbon
-
bonded to four different
groups.
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And I want to to stress that
it's not four different atoms.
-
You could have had a methyl
group here and a propyl group
-
here, and the carbon would still
be bonded directly to a
-
carbon in either case, but that
would still be a chiral
-
carbon, and this would still
actually be a chiral molecule.
-
In the next video, we'll
do a bunch of examples.
-
We'll look at molecules, try
to identify the chiral
-
carbons, and then try to
figure out whether the
-
molecule itself is--
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