Understanding Acids and Bases Concepts

- Let's look at two definitions for acids and bases, Bronsted-Lowry and Lewis, and we'll start with Bronsted-Lowry. A Bronsted-Lowry acid is a proton donor, and a Bronsted-Lowry base is a proton acceptor. Let's really quickly review what a proton refers to. For a neutral hydrogen atom, the most common isotope has one proton in the nucleus. Here's my nucleus, here's my one proton, and one electron outside of the nucleus, so here's my electron. If we take away the electron, we're left with just that proton. We're left with the nucleus of a hydrogen atom, so we could also say this is equal to H+. When you're talking about a proton donor, that's something that's donating an H+, and a proton acceptor is accepting that H+. Let's go down here to the dot structure for HCl, and let's focus in on that covalent bond. One of those electrons came from the chlorine, so let me go ahead and draw in that electron here. One of the electrons in the bond came from the chlorine and one of the electrons in the bond came from the hydrogen, so in magenta right here. That's talking about this electron right here. HCl is going to donate a proton to water, so let's go ahead and show what happens. A lone pair of electrons on the oxygen is going to pick up this proton right here, and the electron in magenta is left behind, so these two electrons come off onto the chlorine. Let's go ahead and draw the product, so we would have, we had an oxygen bonded to two hydrogens, but the oxygen just picked up a proton, so now it's bonded to three, which gives the oxygen a +1 formal charge. Let's show those electrons. These two electrons in here in red are going to pick up this proton, and those two electrons in red are going to form this bond right here. This is H3O+ or hydronium, the hydronium ion. The chlorine becomes the chloride anions. Let's go ahead and draw that in. We had three lone pairs of electrons. We got one more lone pair, so the electron in green is on the chlorine and so is the electron in magenta. The chlorine picked up a negative charge. It becomes an anion, so we get the chloride anion here. The HCl donated a proton, so it's a proton donor. It's a Bronsted-Lowry acid. Let me go ahead and write that here. Bronsted-Lowry acid, and water accepted the proton. It accepted an H+. Water is the Bronsted-Lowry base. Let's think about the possibility of the reverse reaction. If you think about what must happen, the chloride anion must function as a base and pick up a proton from the hydronium ion here. If you think about the reverse reaction, I'll put a really tiny arrow going back in reverse, because the equilibrium lies far to the right. If you think about it in reverse, the chloride anion would function as a base. This is actually the conjugate base to HCl, so let me go ahead and write that here. Conjugate base to HCl. We have a conjugate acid-base pair here, so let me go ahead and write that over here. We have HCl and Cl-. Think about the difference between these two. There's one H+ difference between that conjugate acid-base pair. Over here, water functions as a base. Once it picks up a proton over here, it could function as an acid. This would be the conjugate acid, so let me go ahead and write that. This is the conjugate acid to our base over here, to water. We have another conjugate acid-base pair, so let me go ahead and write that over here. We have H2O, H2O and H3O+ is another conjugate acid-base pair, and once again, think about the difference between these two, between H2O and H3O+. There's one proton difference. One H+ difference. When you're dealing with the Bronsted-Lowry definitions for acids and bases, think about one proton. Let's move onto the Lewis definitions, and let's get some room down here. The Lewis definition. A Lewis acid is an electron pair acceptor, and a good way to remember that is we have an A here for acid, and then electron pair acceptor, so an A right here. A Lewis base is an electron pair donor, and a good way to remember this is if you have Lewis base, so a lower-case B for base. Over here, electron pair donor. If you take this B here and just flip it, then you would get a D. That's a nice way to remember that a Lewis base is an electron pair donor. Let's look at the dot structure here for boron trifluoride. Notice that boron does not have an octet. If we count the number of electrons, here's two, four, six electrons around it. It's not an octet. This boron right here, let me go ahead and draw this in. This boron is sp2 hybridized. If it's sp2 hybridized, it has an empty P orbital. We have an empty orbital, which I'm going to represent like this, and that empty orbital is capable of accepting a pair of electrons. Boron trifluoride is going to function as a Lewis acid here. Water has a lone pair of electrons that it can donate, so water's going to function as a Lewis base. Lone pair of electrons on the oxygen. We're going to donate that lone pair into the empty orbital here. We're going to form a bond between the oxygen and the boron. Let's go ahead and do that. The oxygen was bonded to two hydrogens already. We're going to form a bond between the oxygen and the boron, and this oxygen still has one lone pair of electrons left, which is going to give this oxygen here a +1 formal charge. The boron is bonded to three fluorines, and I'm just not going to draw in the lone pairs of electrons around fluorine to save some time here. This gives the boron a -1 formal charge. Let's show those electrons. Let me go ahead and highlight this electron pair in red here. This pair of electrons gets donated to boron to form this bond right here. Notice there's no H+ changing here, and so that's why the Bronsted-Lowry definition doesn't apply to this acid-base reaction. We have to use the Lewis definition. The Lewis definition is a little bit more broad, actually, and we can go back up here to the previous reaction, and we can look at the definition for Lewis acid and base for this one. A Lewis base is an electron pair donor, and notice that's what water is doing here as well. It's donating a pair of electrons. Not only can we say this is a Bronsted-Lowry base, we could also say this is a Lewis base. What's accepting that pair of electrons? Well, it's the protons. Let me go ahead and draw this out. HCl, you could think about HCl as being H+ and Cl-. That lone pair of electrons, this pair of electrons is being accepted by the proton, so you could say that this proton here is a Lewis acid. Let me go ahead and use a different color for that. We could say that this proton here is a Lewis acid. It's accepting a pair of electrons. You could say that HCl is a source of a Lewis acid, which is H+. These are very important definitions to understand.

- Let&#39;s look at two definitions for acids and bases,
Bronsted-Lowry and Lewis, and we&#39;ll start with Bronsted-Lowry. A Bronsted-Lowry acid is a proton donor, and a Bronsted-Lowry base
is a proton acceptor. Let&#39;s really quickly review
what a proton refers to. For a neutral hydrogen atom, the most common isotope has
one proton in the nucleus. Here&#39;s my nucleus, here&#39;s my one proton, and one electron outside of the nucleus, so here&#39;s my electron. If we take away the electron, we&#39;re left with just that proton. We&#39;re left with the
nucleus of a hydrogen atom, so we could also say this is equal to H+. When you&#39;re talking about a proton donor, that&#39;s something that&#39;s donating an H+, and a proton acceptor
is accepting that H+. Let&#39;s go down here to the
dot structure for HCl, and let&#39;s focus in on that covalent bond. One of those electrons
came from the chlorine, so let me go ahead and
draw in that electron here. One of the electrons in the
bond came from the chlorine and one of the electrons in the bond came from the hydrogen,
so in magenta right here. That&#39;s talking about
this electron right here. HCl is going to donate a proton to water, so let&#39;s go ahead and show what happens. A lone pair of electrons on the oxygen is going to pick up
this proton right here, and the electron in
magenta is left behind, so these two electrons
come off onto the chlorine. Let&#39;s go ahead and draw the
product, so we would have, we had an oxygen bonded to two hydrogens, but the oxygen just picked up a proton, so now it&#39;s bonded to three, which gives the oxygen a +1 formal charge. Let&#39;s show those electrons. These two electrons in here in red are going to pick up this proton, and those two electrons in red are going to form this bond right here. This is H3O+ or hydronium,
the hydronium ion. The chlorine becomes the chloride anions. Let&#39;s go ahead and draw that in. We had three lone pairs of electrons. We got one more lone pair, so the electron in
green is on the chlorine and so is the electron in magenta. The chlorine picked up a negative charge. It becomes an anion, so we
get the chloride anion here. The HCl donated a proton,
so it&#39;s a proton donor. It&#39;s a Bronsted-Lowry acid. Let me go ahead and write that here. Bronsted-Lowry acid, and
water accepted the proton. It accepted an H+. Water is the Bronsted-Lowry base. Let&#39;s think about the possibility
of the reverse reaction. If you think about what must happen, the chloride anion must function as a base and pick up a proton from
the hydronium ion here. If you think about the reverse reaction, I&#39;ll put a really tiny
arrow going back in reverse, because the equilibrium
lies far to the right. If you think about it in reverse, the chloride anion would
function as a base. This is actually the
conjugate base to HCl, so let me go ahead and write that here. Conjugate base to HCl. We have a conjugate acid-base pair here, so let me go ahead and
write that over here. We have HCl and Cl-. Think about the difference
between these two. There&#39;s one H+ difference between that conjugate acid-base pair. Over here, water functions as a base. Once it picks up a proton over here, it could function as an acid. This would be the conjugate acid, so let me go ahead and write that. This is the conjugate acid to
our base over here, to water. We have another conjugate acid-base pair, so let me go ahead and
write that over here. We have H2O, H2O and H3O+ is another conjugate acid-base pair, and once again, think about the difference
between these two, between H2O and H3O+. There&#39;s one proton difference. One H+ difference. When you&#39;re dealing with the
Bronsted-Lowry definitions for acids and bases,
think about one proton. Let&#39;s move onto the Lewis definitions, and let&#39;s get some room down here. The Lewis definition. A Lewis acid is an electron pair acceptor, and a good way to remember that is we have an A here for acid, and then electron pair
acceptor, so an A right here. A Lewis base is an electron pair donor, and a good way to remember this is if you have Lewis base,
so a lower-case B for base. Over here, electron pair donor. If you take this B here and just flip it, then you would get a D. That&#39;s a nice way to remember that a Lewis base is
an electron pair donor. Let&#39;s look at the dot structure
here for boron trifluoride. Notice that boron does not have an octet. If we count the number of electrons, here&#39;s two, four, six electrons around it. It&#39;s not an octet. This boron right here, let
me go ahead and draw this in. This boron is sp2 hybridized. If it&#39;s sp2 hybridized,
it has an empty P orbital. We have an empty orbital, which I&#39;m going to represent like this, and that empty orbital is capable of accepting a pair of electrons. Boron trifluoride is going to
function as a Lewis acid here. Water has a lone pair of
electrons that it can donate, so water&#39;s going to
function as a Lewis base. Lone pair of electrons on the oxygen. We&#39;re going to donate that lone pair into the empty orbital here. We&#39;re going to form a bond
between the oxygen and the boron. Let&#39;s go ahead and do that. The oxygen was bonded to
two hydrogens already. We&#39;re going to form a bond
between the oxygen and the boron, and this oxygen still has one
lone pair of electrons left, which is going to give this
oxygen here a +1 formal charge. The boron is bonded to three fluorines, and I&#39;m just not going
to draw in the lone pairs of electrons around fluorine
to save some time here. This gives the boron a -1 formal charge. Let&#39;s show those electrons. Let me go ahead and highlight this electron pair in red here. This pair of electrons
gets donated to boron to form this bond right here. Notice there&#39;s no H+ changing here, and so that&#39;s why the
Bronsted-Lowry definition doesn&#39;t apply to this acid-base reaction. We have to use the Lewis definition. The Lewis definition is a
little bit more broad, actually, and we can go back up here
to the previous reaction, and we can look at the definition for Lewis acid and base for this one. A Lewis base is an electron pair donor, and notice that&#39;s what
water is doing here as well. It&#39;s donating a pair of electrons. Not only can we say this
is a Bronsted-Lowry base, we could also say this is a Lewis base. What&#39;s accepting that pair of electrons? Well, it&#39;s the protons. Let me go ahead and draw this out. HCl, you could think about
HCl as being H+ and Cl-. That lone pair of electrons, this pair of electrons is
being accepted by the proton, so you could say that this
proton here is a Lewis acid. Let me go ahead and use a
different color for that. We could say that this
proton here is a Lewis acid. It&#39;s accepting a pair of electrons. You could say that HCl is a source of a Lewis acid, which is H+. These are very important
definitions to understand.

Transcript for:Understanding Acids and Bases Concepts

Transcript for:
Understanding Acids and Bases Concepts