Electronegativity | Atomic structure and properties | AP Chemistry | Khan Academy
Summary
TLDRThis video script explores electronegativity and electron affinity, explaining how they relate to an atom's attraction to electrons. It uses the example of a water molecule to illustrate how differing electronegativities between hydrogen and oxygen create partial charges, affecting water's properties. The script also discusses how electronegativity trends across the periodic table, increasing from left to right and decreasing from top to bottom, influencing chemical reactivity and bonding.
Takeaways
- 🔬 Electronegativity and electron affinity are closely related concepts in chemistry.
- 🌐 Electron affinity refers to an atom's attraction to electrons, while electronegativity specifically describes how an atom behaves when sharing electrons in a covalent bond.
- 🐷 'Hogging electrons' is an informal way to describe an atom's tendency to attract electrons towards itself within a covalent bond.
- 💧 The water molecule (H2O) is used as an example to illustrate how electronegativity affects the sharing of electrons between different atoms.
- ⚛️ Hydrogen atoms in a water molecule are stable when they share electrons with oxygen, which has a higher electronegativity and thus attracts the shared electrons more strongly.
- 🚫 The unequal sharing of electrons due to differing electronegativities results in a polar covalent bond, leading to partial charges on the atoms.
- 📚 Understanding electronegativity is crucial for predicting chemical reactions and the formation of molecules, especially in organic chemistry.
- ⬅️ Electronegativity increases from left to right across a period in the periodic table, as atoms become more stable by gaining electrons.
- ⬇️ Electronegativity decreases as you move down a group in the periodic table due to the increasing distance of the outermost electrons from the nucleus.
- 🏔️ The most electronegative elements are found at the top right of the periodic table, while the least electronegative are at the bottom left.
Q & A
What are the main concepts discussed in the video?
-The video discusses the concepts of Electronegativity and Electron Affinity, explaining how they relate to an atom's attraction to electrons and its behavior in covalent bonds.
How is Electron Affinity defined in the context of the video?
-Electron Affinity is defined as the measure of how much an atom attracts electrons or its desire to gain additional electrons.
What does it mean to 'hog electrons' in the context of electronegativity?
-To 'hog electrons' refers to an atom's tendency to attract and keep electrons closer to itself rather than sharing them equally in a covalent bond.
Why is the water molecule used as an example in the video?
-The water molecule is used as an example because it illustrates the difference in electronegativity between hydrogen and oxygen, which results in polar covalent bonds.
How does the video explain the electron configuration of hydrogen and oxygen in a water molecule?
-The video explains that hydrogen atoms have one valence electron and would be stable if they could gain another electron, while oxygen has six valence electrons and would be stable if it could gain two more electrons to complete its octet.
What is the significance of electronegativity differences in the formation of water molecules?
-The difference in electronegativity between oxygen and hydrogen causes the electrons in the covalent bonds to spend more time around the oxygen, leading to a partial negative charge on the oxygen and partial positive charges on the hydrogens, which contributes to water's unique properties.
How does electronegativity affect the properties of a molecule?
-Electronegativity differences between atoms in a molecule can lead to polar bonds, which in turn affect the molecule's physical and chemical properties, such as solubility and reactivity.
What trend does electronegativity follow as you move across a period in the periodic table?
-Electronegativity increases from left to right across a period in the periodic table because atoms on the right side have a greater tendency to attract electrons due to higher nuclear charge.
What trend does electronegativity follow as you move down a group in the periodic table?
-Electronegativity decreases as you move down a group because the outermost electrons are farther from the nucleus and are less attracted to it, making the atom less likely to attract additional electrons.
Which elements are considered the most electronegative?
-The most electronegative elements are found in the top right of the periodic table, such as the halogens.
Which elements are considered the least electronegative?
-The least electronegative elements are found in the bottom left of the periodic table, such as the alkali metals and alkaline earth metals.
Outlines
🔬 Electronegativity and Electron Affinity
This paragraph introduces the concepts of electronegativity and electron affinity. Electronegativity refers to the tendency of an atom to attract electrons when it is part of a covalent bond, essentially how much it 'hogs' electrons from another atom it's bonded with. Electron affinity, on the other hand, is the measure of an atom's attraction to additional electrons. The paragraph explains that these two concepts are closely related, with atoms that have high electronegativity also tending to have high electron affinity. The example of a water molecule (H2O) is used to illustrate these concepts, highlighting how hydrogen and oxygen atoms share electrons to achieve stability, with oxygen being more electronegative and thus hogging the electrons more, leading to a polar molecule with distinct partial charges.
📈 Trends in Electronegativity
This paragraph discusses the trends in electronegativity across the periodic table. It starts by explaining that electronegativity increases as you move from left to right within a period, using sodium and chlorine as examples. Sodium, being a group one element, is more likely to lose an electron to achieve a stable electron configuration like neon, while chlorine, being a halogen, would prefer to gain an electron to complete its outer shell like argon. Consequently, chlorine is more electronegative than sodium. The trend continues as you move down a group, with electronegativity decreasing. This is because atoms get larger, and their outermost electrons are less attracted to the nucleus, making it easier for them to lose electrons. The most electronegative elements are found at the top right of the periodic table, while the least electronegative are at the bottom left.
Mindmap
Keywords
💡Electronegativity
💡Electron Affinity
💡Covalent Bond
💡Hogging Electrons
💡Valence Electrons
💡Ionization Energy
💡Atomic Radii
💡Partial Charges
💡Periodic Table Trends
💡Noble Gases
💡Electron Configuration
Highlights
Electronegativity and electron affinity are closely related concepts.
Electron affinity measures how much an atom attracts electrons.
Electronegativity is the tendency of an atom to attract electrons in a covalent bond.
Atoms with high electronegativity tend to hog electrons in covalent bonds.
Electronegativity is more specific than electron affinity.
Electronegativity can be understood through the example of a water molecule.
In a water molecule, oxygen is more electronegative than hydrogen.
The difference in electronegativity between oxygen and hydrogen leads to polar covalent bonds in water.
Electronegativity is crucial for understanding chemical reactions and molecular formation.
Electronegativity trends can be predicted by considering ionization energy.
Electronegativity increases from left to right across a period in the periodic table.
Electronegativity decreases as you move down a group in the periodic table.
The most electronegative elements are found at the top right of the periodic table.
The least electronegative elements are found at the bottom left of the periodic table.
Noble gases are not very reactive due to their complete electron shells.
Electronegativity helps predict the likelihood of reactions in organic chemistry.
The trend in electronegativity across the periodic table is from bottom left to top right.
Transcripts
Voiceover: What I want to talk about in this video
are the notions of Electronegativity,
electro, negati, negativity,
and a closely, and a closely related
idea of Electron Affinity, electron affinity.
And they're so closely related that in general,
if something has a high electronegativity,
they have a high electron affinity,
but what does this mean?
Well, electron affinity is how much does that atom
attract electrons, how much does it like electrons?
Does it want, does it maybe want more electrons?
Electronegativity is a little bit more specific.
It's when that atom is part of a covalent bond,
when it is sharing electrons with another atom,
how likely is it or how badly does it want
to hog the electrons in that covalent bond?
Now what do I mean by hogging electrons?
So let me make, let me write this down.
So how badly wants to hog,
and this is an informal definition clearly,
hog electrons, keep the electrons,
to spend more of their time closer to them
then to the other party in the covalent bond.
And this is how, how much they like electrons,
or how much affinity they have towards electrons.
So how much they want electrons.
And you can see that these are very,
these are very related notions.
This is within the context of a covalent bond,
how much electron affinity is there?
Well this, you can think of it as a slightly broader notion,
but these two trends go absolutely in line with each other.
And to think about, to just think about
electronegativity makes it a little bit more tangible.
Let's think about one of the most famous
sets of covalent bonds,
and that's what you see in a water molecule.
Water, as you probably know, is H two O,
you have an oxygen atom,
and you have two hydrogens.
Each of the hydrogen's have one valence electron,
and the oxygen has, we see here, at it's outermost shell,
it has one, two, three, four, five, six valence electrons.
One, two, three, four, five, six valence electrons.
And so you can imagine, hydrogen would be happy
if it was able to somehow pretend like it had another
electron then it would have an electron configuration
a stable, first shell that only requires two electrons,
the rest of them require eight,
hydrogen would feel, hey I'm stable like helium
if it could get another electron.
And oxygen would feel, hey I'm stable like neon
if I could get two more electrons.
And so what happens is they share each other's electrons.
This, this electron can be shared in conjunction
with this electron for this hydrogen.
So that hydrogen can kind of feel like it's using
both and it gets more stable,
it stabilizes the outer shell,
or it stabilizes the hydrogen.
And likewise, that electron could be,
can be shared with the hydrogen,
and the hydrogen can kind of feel more like helium.
And then this oxygen can feel like
it's a quid pro quo,
it's getting something in exchange for something else.
It's getting the electron, an electron,
it's sharing an electron from each of these hydrogens,
and so it can feel like it's, that it stabilizes it,
similar to a, similar to a neon.
But when you have these covalent bonds,
only in the case where they are equally
electronegative would you have a case
where maybe they're sharing,
and even there what happens
in the rest of the molecule might matter,
but when you have something like this,
where you have oxygen and hydrogen,
they don't have the same electronegativity.
Oxygen likes to hog electrons more than hydrogen does.
And so these electrons are not gonna spend
an even amount of time.
Here I did it kind of just drawing these,
you know, these valence electrons as these dots.
But as we know, the electrons are in this
kind of blur around, around the,
around the actual nuclei,
around the atoms that make up the atoms.
And so, in this type of a covalent bond,
the electrons, the two electrons that this bond represents,
are going to spend more time around the oxygen
then they are going to spend around the hydrogen.
And these, these two electrons are gonna spend
more time around the oxygen,
then are going to spend around the hydrogen.
And we know that because oxygen is more electronegative,
and we'll talk about the trends in a second.
This is a really important idea in chemistry,
and especially later on as you study organic chemistry.
Because, because we know that
oxygen is more electronegative,
and the electrons spend more time
around oxygen then around hydrogen,
it creates a partial negative charge on this side,
and partial positive charges on this side right over here,
which is why water has many of the properties that it does,
and we go into much more in depth in that in other videos.
And also when you study organic chemistry,
a lot of the likely reactions that are
going to happen can be predicted,
or a lot of the likely molecules that form
can be predicted based on elecronegativity.
And especially when you start going
into oxidation numbers and things like that,
electronegativity will tell you a lot.
So now that we know what electronegativity is,
let's think a little bit about what is,
as we go through, as we start,
as we go through, as we go through a period,
as say as we start in group one,
and we go to group, and as we go all the way
all the way to, let's say the halogens,
all the way up to the yellow column right over here,
what do you think is going to be
the trend for electronegativity?
And once again, one way to think about it
is to think about the extremes.
Think about sodium, and think about chlorine,
and I encourage you to pause
the video and think about that.
Assuming you've had a go at it,
and it's in some ways the same idea,
or it's a similar idea as ionization energy.
Something like sodium has only one electron
in it's outer most shell.
It'd be hard for it to complete that shell,
and so to get to a stable state it's much easier
for it to give away that one electron that it has,
so it can get to a stable configuration like neon.
So this one really wants to give away an electron.
And we saw in the video on ionization energy,
that's why this has a low ionization energy,
it doesn't take much energy, in a gaseous state,
to remove an electron from sodium.
But chlorine is the opposite.
It's only one away from completing it's shell.
The last thing it wants to do is give away electron,
it wants an electron really, really, really, really badly
so it can get to a configuration of argon,
so it can complete its third shell.
So the logic here is that sodium wouldn't mind
giving away an electron,
while chlorine really would love an electron.
So chlorine is more likely to hog electrons,
while sodium is very unlikely to hog electrons.
So this trend right here,
when you go from the left to the right,
your electronegativity, let me write this,
your getting more electronegative.
More electro, electronegative, as you,
as you go to the right.
Now what do you think the trend is going to be
as you go down, as you go down in a group?
What do you think the trend is going to be as you go down?
Well I'll give you a hint.
Think about, think about atomic radii, and given that,
pause the video and think about
what do you think the trend is?
Are we gonna get more or less electronegative
as we move down?
So once again I'm assuming you've given a go at it,
so as we know, from the video on atomic radii,
our atom is getting larger, and larger, and larger,
as we add more and more and more shells.
And so cesium has one electron in it's outer most shell,
in the sixth shell,
while, say, lithium has one electron.
Everything here, all the group one elements,
have one electron in it's outer most shell,
but that fifty fifth electron,
that one electron in the outer most shell in cesium,
is a lot further away then the outer most electron
in lithium or in hydrogen.
And so because of that, it's, well one,
there's more interference between that electron and the
nucleus from all the other electrons in between them,
and also it's just further away,
so it's easier to kind of grab it off.
So cesium is very likely to give up,
it's very likely to give up electrons.
It's much more likely to give up electrons than hydrogen.
So, as you go down a given group,
you're becoming less, less electronegative, electronegative.
So what, what are, based on this,
what are going to be the most electronegative
of all the atoms?
Well they're going to be the ones
that are in the top and the right of the periodic table,
they're going to be these right over here.
These are going to be the most electronegative,
Sometimes we don't think as much about the noble gases
because they aren't, they aren't really that reactive,
they don't even form covalent bond,
because they're just happy.
While these characters up here,
they sometimes will form covalent bonds,
and when they do, they really like to hog those electrons.
Now what are the least electronegative,
sometimes called very electropositive?
Well these things down here in the bottom left.
These, over here, they have only,
you know in the case of cesium,
they have one electron to give away
that would take them to a stable state like, like xenon,
or in the case of these group two elements
they might have to give away two,
but it's much easier to give away two
then to gain a whole bunch of them.
And they're big, they're big atoms.
So those outer most electrons are getting
less attracted to the positive nucleus.
So the trend in the periodic table
as you go from the bottom left,
to the top right,
you're getting more, more electro, electronegative.
5.0 / 5 (0 votes)