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In the previous videos
we've talked about only
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the first ionization energy.
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In this video, we're
going to compare
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the first and the second
ionization energies,
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and we're going to use
lithium as our example.
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So in the previous
video, we already
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know that lithium has
an atomic number of 3,
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so there are three
protons in the nucleus.
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In a neutral atom of lithium,
the number of electrons
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equals the number of
protons, and so we
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know there are three
electrons in lithium here.
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The electron
configuration is 1s2 2s1.
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So we have two electrons
in the 1s orbital
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so we can go ahead
and put those two
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electrons in the 1s
orbital like that.
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And then we have
one more electron,
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and that electron's going to go
into the 2s orbital like this.
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And so that would be
a very simple picture
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of the neutral lithium atom.
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If we apply enough
energy, we can actually
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pull away this
outer electron here.
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So we can pull
away that electron,
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and we call this the
first ionization energy.
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And to pull away
that electron takes
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approximately 520
kilojoules per mole.
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And so once we've pulled
that electron away,
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we no longer have a neutral
lithium atom, right?
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We would have a lithium
ion because we would still
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have three positive
charges in the nucleus,
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but we have only two
negative charges now.
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We only have two electrons
because we pulled one away.
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So 3 minus 2 gives us plus 1.
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So this is the
lithium plus 1 cation.
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And the electron
configuration would just
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be 1s2 because we lost the
electron in the 2s orbital.
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And so we could keep going.
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We could apply some more energy
and pull away another electron.
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So let's say that we pull
away this electron this time.
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OK, so we're taking a
second electron away,
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and so we wouldn't call
this ionization energy 1.
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We would therefore call
this ionization energy 2
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because this is to take
away the second electron.
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And this value turns out to be
approximately 7,298 kilojoules
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per mole.
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And so if we take away that
second electron, once again
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we still have three positive
charges in the nucleus,
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but we have only one
negative charge now.
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There's only one electron
so this is no longer
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the lithium plus 1 cation.
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This is the lithium plus
2 cation because 3 minus 1
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is plus 2.
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So this is lithium plus 2 here,
and the electron configuration
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would be only one electron
in a 1s orbital, so 1s1.
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So we can see that there
is a big difference
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between the first
ionization energy
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and the second ionization
energy, so 520 versus 7,298.
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So let's see if we can
explain the reasoning
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for this extremely large
difference in ionization
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energies.
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And we're going to use the
three factors that we've
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talked about in the
previous videos.
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So the first factor we
discussed was nuclear charge,
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which refers to the number
of protons in the nucleus.
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So if we look at the
neutral lithium atom,
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three positive charges
in the nucleus.
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That positive charge
is what's going
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to attract this electron
in magenta here.
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And if we look at
the lithium plus 1
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cation, similar situation.
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We still have three
protons in the nucleus,
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and so that positive
charge is what's
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going to be attracting
this electron as well.
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And so because of the
same number of protons,
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we have to think more about
effective nuclear charge, as
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opposed to how many protons
there are in the nucleus.
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And before we do that,
we have to consider
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the effect of
electron shielding.
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So let's talk about
electron shielding next.
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So electron shielding, also
called electron screening,
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so electron shielding
slash screening.
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So when we think about
electron shielding,
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we're thinking about the
inner orbital electrons here.
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So going back to the
neutral lithium atom,
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these two inner shell
electrons right here
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are going to repel this
outer shell electron.
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So this one is going to
repel this one as well.
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And so we can think about it
as they screen the electron
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in magenta from feeling the full
force of the positive 3 charge
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in the nucleus because
electrons repel other electrons.
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And so the way to calculate
the effect of nuclear charge--
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so we've done this in
the previous videos
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as well-- the simple
way of calculating
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effective nuclear charge is
take the number of protons,
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so plus 3, and from
that you subtract
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the number of
shielding electrons.
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So in this case, it would
be these two electrons
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in the 1s orbital.
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So 3 minus 2 gives us an
effective nuclear charge
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of plus 1.
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And so the electron
in magenta isn't
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feeling a nuclear
charge of plus 3.
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It's really only feeling an
effective nuclear charge close
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to positive 1 because the actual
value is approximately 1.3
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when you do the more
complicated calculations.
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And so the effect of
electron shielding
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is to decrease the
overall nuclear charge
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that this electron
magenta feels.
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And so when we move over
here to this electron,
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so I'm talking about
this electron in magenta
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for the lithium
plus 1 cation, it's
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not the same situation, right?
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There's not much
electron shielding.
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This electron over here
might repel it a little bit,
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but there are no
inner shell electrons
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repelling this
electron in magenta.
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And because of that,
the electron in magenta
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is going to feel this
positive 3 charge, much
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more of the full positive
3 charge of the nucleus.
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And so therefore,
there's going to be
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a much greater
attractive force holding
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this electron in
magenta to this nucleus.
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And therefore, you have
to apply more energy
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to pull that electron away.
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So the effect of
electron shielding
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tells you the second
electron is much harder
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to remove than the
first, and so we
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see a large increase
in ionization energy
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from the first ionization
energy to the second ionization
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energy.
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The last factor that we
discussed was distance,
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so the distance of those
electrons in magenta
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from the nucleus.
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So on the left, once again going
back to the neutral lithium
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atom, this electron is in
the second energy level.
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So it's further away
than this electron.
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This electron is in the first
energy level, in the 1s2,
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so this distance here is smaller
than the distance on the left.
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And so since the
distance is smaller,
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this electron in
magenta feels more
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of an attractive force
from the nucleus.
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Once again, that's
Coulomb's law.
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And so therefore, there's an
increased attractive force.
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Therefore, you take more energy
to pull that electron away.
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So it takes much more energy
to pull the second electron
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away than the
first, and so that's
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why we see an increase
in ionization energy.
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So distance says the fact
that this electron is closer
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means it takes more
energy to pull it away,
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and that's another
reason why this number
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for the second
ionization energy is
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so much larger than the first.
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So it takes a heck
of lot more energy
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to pull away your
second electron.
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And that explains why we
see lithium forming a plus 1
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cation, because it doesn't take
anywhere near as much energy
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to pull away one electron
as it does to take away two
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to form a lithium 2 plus.
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And so this is one way to tell
what kind of an ion will form.
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Look at the ionization energies,
and when you see a huge jump,
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that clues you in as to which
ions are easier to form.
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Khan Academy
