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- [Instructor] Let's
draw Lewis dot structures
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for certain molecules, it's a
lot of fun to do that, okay?
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Now the first thing we need to do
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to draw these structures
is to identify the number
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of valence electrons, okay?
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And we've talked about these
valence electrons in our
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previous videos, but this
is such a central concept,
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so just let's quickly recap.
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Valence electrons represents the number
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of electrons in the outermost shell, okay?
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And if we bring up our
periodic table, then
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the valence electrons for
all the elements belonging
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to a particular group is given this way.
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So the first group will
have the elements of,
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the first group will have
one valence electron.
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The elements of the second
group will have two electrons
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in its outermost shell,
two valence electrons,
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and so on and so forth.
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When it comes to group 18,
helium is an exception.
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It has two valence electrons,
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but the rest of them will
have eight valence electrons,
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eight electrons, and its
outermost shell, okay?
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And just to get a sneak peek
of why this is the case,
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here are some structures
of some of the elements.
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You can see hydrogen, one
electron in its outermost shell.
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Lithium, one electron
in its outermost shell.
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Sodium, which has total of 11 electrons,
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but one electron in its outermost shell.
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Same thing will continue.
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Okay, but what about the
elements of these group?
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What about their valence electrons?
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Well, we don't have to worry about them,
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because we are drawing
structures for molecules
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that are formed by covalent bonds.
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Meaning bonds formed by
sharing of electrons.
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Now, metals, which I've
drawn in red, okay?
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They usually do not participate
in covalent bonds, okay?
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It's only the non-metals
that usually do that.
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And the non-metals are in green.
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And you can see all the valence electrons
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for the non-metals we already have them.
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So we only got to worry about them
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and not worry too much about these, okay?
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All right, with that recap,
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let's now draw the Lewis
structure for hydrogen.
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So the first step is how
many valence electrons
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does hydrogen have?
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It has one valence electron.
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So let's write that, one valence electron.
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And now, hydrogen would
love to have two electrons
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because it'll make it stable
in its outermost shell.
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And how do I know that?
Because if I look at helium,
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look, helium has two electrons
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and it doesn't bond with anybody.
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Because helium is stable,
all noble gases are stable.
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That's how I know hydrogen will love
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to have two electrons
in its outermost shell.
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Now that means it needs one more electron.
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And here's the thing, if
it needs one more electron,
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it's gonna say, "Hey, I'm
gonna share one electron."
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If you need one, you share one, okay?
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So hydrogen says, "Hey, I'm willing
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to share my one valence electron."
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So it's gonna share one electron.
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And if somebody else is willing
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to share their one valence electron,
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it's gonna form a nice
bond with them, okay?
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That's why it forms a bond with itself.
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And so now we can draw
the structure this way.
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So here's the hydrogen, and
here is the valence electron.
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And it's ready to share that.
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Here's another hydrogen,
here's the valence electron
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it's ready to share that.
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And look, they're gonna form a bond.
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This is called the covalent bond.
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And by sharing, each atom
has access to two electrons,
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making them both stable.
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That's why they stay
together, okay? Covalent bond.
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How do we draw the Lewis
structure, the final structure?
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Well, we are just gonna
represent this bond
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with a single line.
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So a single line represents
a bond between two electrons.
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Okay?
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This is the Lewis dot
structure for hydrogen.
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Okay, let's take another example.
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Let's take oxygen.
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If I go over here, oxygen
has six valence electrons,
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that's where we start.
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Oxygen has six valence electrons.
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And how many does it
need to attain stability?
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Well, if you look at
neon, then you can see
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that it has eight electrons
in its outermost shell,
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and I know neon is very stable
so that helps me understand
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that eight electrons
in the outermost shell
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gives you stability.
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In fact, that is the case
for most other elements.
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For hydrogen it's two, but
for most other elements,
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they require eight electrons
in its outermost shell.
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We call this the octet rule, all right?
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So since oxygen requires eight electrons
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in it's outermost shell, it has six.
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So it needs two more.
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If you need to, you share
two, that's the rule, okay?
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So it's going to share two electrons.
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And if somebody else is willing
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to share their two electrons,
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it's gonna form a bond with them.
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That's why it forms a
bond with itself, okay?
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So how do we do that?
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Well, again, we're gonna draw two.
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So we're gonna draw the Lewis structure.
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We're gonna draw two oxygen atoms.
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And now since it has six valance electron,
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here's how I show the
valence electrons, okay?
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One, two, three, four, five, six.
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Why do I draw it this way?
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Because just by drawing
it this way, again,
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you can see just from the dot structure
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that there's one pair,
there's a second pair,
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oh, there's no pair here, oh,
there's no pair over here.
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These electrons are lonely,
they want to get paired.
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And that's how I know
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that these two electrons are
gonna participate in bonding.
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It's gonna be shared.
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So just by looking at the
dot structure, I can see
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that it's going to share two electrons.
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That's another way to just confirm
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the same thing that we
got over here, okay?
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So it's gonna share these two electrons.
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This oxygen atom is
gonna do the same thing,
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one, two, three, four, five, six.
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It's gonna share these two,
which means these two electrons
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and these two electrons can form a bond.
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Now, just to make it a
little convenient for me
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to draw this, I'm gonna show
the lonely electron here,
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I'm gonna show the pair over here.
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You can draw the pair
wherever you want, okay?
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It just makes it so much
convenient to draw bonds over here.
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So this means these two electrons
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are gonna form a bond over here.
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And these two electrons are
gonna form a bond over here.
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And there you have it, that
means oxygen is gonna form
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a double bond, and you
can count the number of,
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because of this covalent
bond, you can count the number
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of electrons each oxygen
has access to now.
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If you look at this oxygen,
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it has one, two, three, four,
five, six, seven, eight,
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it has eight electrons access to it.
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And this oxygen, one, two, three,
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four, five, six, seven, eight,
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it has also eight electrons access to.
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And so octet rule is satisfied.
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And so now how do we draw
the final Lewis structure?
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Well, here's the oxygen
atoms, one and two.
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So two bonds, two lines,
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and then we have to show the lone pairs.
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These are called lone pairs
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because hey do not participate in bonding,
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but it's important to show them.
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So here's the lone pairs.
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You can show the lone pairs
wherever you want, okay?
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But do show them in the
Lewis dot structure.
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And there you have it,
that is a dot structure.
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All right, your turn,
why don't you try drawing
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a Lewis dot structure for N2?
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Why don't you pause the
video and give it a try?
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All right, here we go.
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Again, I look at nitrogen over here,
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and I know that nitrogen
has five valence electrons.
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That's where you always start,
number of valence electrons.
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And octet rule, remember,
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most elements follow the octet rule.
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So it requires eight electrons
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and it's outermost shell for stability.
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It has five, so it needs three more.
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If you need three, you share three.
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So it shares three electrons.
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And again, if it can find some other atom
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or elements that can
share three electrons,
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it'll happily bond with them.
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That's why it forms a bond with itself.
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And so how are we gonna show that?
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Same way.
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So we're gonna draw the five
valence electrons over here
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in the same way we wrote it over here.
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One, two, three, four, five.
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And again, you can see just
by drawing the dot structure,
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we can see there's one pair over here.
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But there are three lonely
electrons, which would love
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to participate in bonding.
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That's why it shares three electrons.
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Just by looking at the dot structure,
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you can confirm that.
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Same thing over here, one,
two, three, four, five.
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So these three electrons
can bond with these three.
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And again, just to make it
a little convenient to draw.
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Okay, I'm gonna...
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Sorry, I'm gonna draw that pair over here,
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and I'm gonna draw that pair over here.
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All right, and of course,
the more practice we get,
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the better we'll be at
conveniently drawing them, okay?
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But anyways, now that we
have these three electrons,
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they can form a bond with each other.
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And so bond number one, bond
number two, bond number three.
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So nitrogen forms a
triple bond with itself.
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And again, if you count the number
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of electrons, this nitrogen has
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one, two, three, four,
five, six, seven, eight.
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And for this nitrogen, again,
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one, two, three, four,
five, six, seven, eight.
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Octet rule is satisfied.
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So what does the Lewis dot structure,
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final structure look like?
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Well, I have three bonds, so
it's gonna be a triple bond.
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And then do not forget the lone pairs.
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Never ever forget the lone pairs, okay?
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And this now explains why nitrogen
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loves to form three bonds.
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Either a triple bond or a
double bond with one element
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and a single bond with another element,
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or three separate bonds.
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And oxygen, for example,
loves to form two bonds.
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Double bonds with another
atom or two single bonds.
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All right, let's kick
things up a little bit.
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How about we draw one for water molecules?
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Hmm, things are getting interesting now.
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The idea is the same though.
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You start with the number of
valence electrons for each one,
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and then think about how much they share
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and then try to form a bond.
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Now of course, because you
have three elements over here,
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there could be a little bit confusion
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about how they're all connected.
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The general rule is the element which is
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on the leftmost side
of the periodic table.
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Again, if here's a period
table, look at the one
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that's on the leftmost side,
which is least electronegative.
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Or you can also think
of it as most metallic,
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because, you know, all metals
are on the left side, right?
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So the one that is on the
leftmost side will usually be
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the central atom, right?
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What about hydrogen?
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Hydrogen is the leftmost,
but it is an exception.
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All right? So hydrogen will
always be on this side.
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So except for hydrogen, any
other elements that you have,
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you have to consider the one
that's on the leftmost side,
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that will be your central atom.
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We'll take more examples,
it'll make sense,
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but at least when it comes to water,
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since hydrogen will always be on the side,
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the oxygen will be in the center,
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so we can immediately draw the structure.
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So the oxygen will be in the center,
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the two hydrogens will be connected to it.
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And we already know their valence
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electrons and how much
they're gonna share.
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So I'm gonna write one for oxygens.
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I'm gonna start with that same technique,
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one, two, three, four, five, six.
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So it's gonna share these two.
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And hydrogen just has one.
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And so you can kind of see
these two are gonna form
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a bond with these two.
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And again, just for convenience,
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what I'm gonna do is I'm gonna take this
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and put that pair here
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so that I can nicely bond of these two.
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And there you have it.
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So this is gonna be bond number one,
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and this will be bond number two.
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And that's it, that's the structure.
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So dot structure.
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So it's gonna be oxygen,
hydrogen, hydrogen,
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one bond here, one bond here.
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And do not forget the lone pairs.
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Okay, again, your turn.
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How about you draw one for NH3?
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Pause and try.
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All right, there are
four elements over here,
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but again, because hydrogen
will always be on the side,
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we know it's the nitrogen which is going
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to be the central atom.
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And the three hydrogen
will be connected to it.
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So nitrogen will be in the center
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and the three hydrogen,
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well, we can draw the three
hydrogens wherever we want.
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So lemme just draw them over here.
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And again, we'll start
by drawing the central,
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the valence electrons on the central atom.
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So one, two, three, four, five.
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I know it has five valence electrons.
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So where do I draw them?
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I'm gonna draw the fifth one over here.
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You can see that, right?
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Now I can conveniently
draw the bonds over here
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and one valence electron for hydrogen.
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It's way to share that.
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So one bond over here,
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one bond over here,
and one bond over here.
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And this will be the lone pair.
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And again, you can check,
hydrogen has access
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to two electrons, nitrogen has access to
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one, two, three, four,
five, six, seven, eight.
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Okay, so what's the final
structure going to be?
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Well, I have N and I have
single bond H, single bond H,
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single bond H.
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Am I forgetting something?
Yes, the lone pair.
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Do not forget the lone pairs.
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All right, final challenge.
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Carbon dioxide.
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So carbon is a new element for us now.
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Why don't you pause the video,
look at the periodic table
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and try to draw the Lewis
structure for this one?
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All right, since carbon is a new one,
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we need to think about carbon.
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Carbon has four valence
electrons and it needs four more.
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And therefore, so lemme
just write that down.
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Four valence electrons,
it needs four more.
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If you need four, you share four.
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Okay, and now, now is an interesting one.
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I don't have hydrogens,
I have carbon and oxygen.
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How do I know which is the
element that comes in the center?
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But again, CO2 might be simpler,
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you might be able to guess it,
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but we're gonna look at which
one is the leftmost element.
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And you can see carbon is the leftmost
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element on the periodic table.
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Oxygen is over here, carbon is over here.
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So carbon comes in the center.
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All right, so carbon will be in the center
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and oxygen will be attached to it.
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So I'm gonna draw two
oxygen atoms over here.
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And now again, I can draw the
Lewis structure for carbon.
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How do I do that? I'm gonna
show the four valence electrons.
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One, two, three, four,
and that's all there is.
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And look, they're all lonely,
they're all four lonely
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and therefore they're gonna
share all four of them
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to form pairs.
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And the same thing for
oxygen as we've done before.
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One, two, three, four, five and six.
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Where should I draw five and six?
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Well, lemme see.
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I mean, we can draw it anywhere, right?
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So lemme draw the five and six here.
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Okay, same thing over here,
one, two, three, four.
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I'm gonna draw the fifth
and the sixth one over here.
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So we can bond this and we can bond this
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and we can kind of bond this
and we can kind of bond this.
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It's a little crooked, but it's okay.
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We get the idea across.
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So this is one pair and then
we can bond it over here
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and we can bond it over here.
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It's fine, it's fine.
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I know it looks a little weird,
but we get the gist of it.
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Carbon is gonna form a double
bond with this oxygen atom
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and the carbon is also gonna form
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a double bond with this oxygen atom.
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And let's count carbon
has one, two, three,
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four, five, six, seven, eight.
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What about oxygen?
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One, two, three, four,
five, six, seven, eight.
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And the same thing with this one.
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And so we can now draw a
better Lewis final structure.
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So carbon, oxygen, oxygen.
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So two bonds.
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So double bond here, a
double bond over here.
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Do not forget the lone pairs.
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So there are two lone pairs over here.
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Lemme draw them over here and here.
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And there are two lone pairs over here.
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Are there any lone pairs on the carbon?
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No, there are no lone pairs on the carbon.
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So there you have it.
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That was fun, right?
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