Let's look at this acid-base reaction. So water's gonna function as a base, and it's gonna take a proton off of a generic acid, H-A. So a lone pair of electrons on the oxygen pick up this proton, leaving these electrons behind on the A.
So oxygen... Oxygen is now bonded to three hydrogens, right? So it picked up a proton.
That's gonna give this oxygen a plus one formal charge, and we can follow those electrons. So these two electrons in red here are gonna pick up this proton. forming this bond, so we make hydronium, H3O+.
And these electrons in green right here are going to come off onto the A to make A minus. Let's go ahead and draw that in. So we're gonna make A minus. Let me draw these electrons in green and give this a negative charge like that. So let's analyze what happened.
HA donated a proton, so this is our Bronsted-Lowry acid. Once HA donates a proton, we're left with the conjugate base, which is A minus. Water, H2O accepted a proton, so this is our Bronsted-Lowry base, and then once H2O accepts a proton, we turn it into hydronium H3O plus, so this is the conjugate acid. So H3O plus is the conjugate acid, and then A minus would be a base.
So if you think about the reverse reaction, H3O plus donating a proton to A minus, then you would get back H2O and HA. Once this reaction reaches equilibrium, we can write an equilibrium expression. And we're gonna consider the stuff on the left to be the reactants, so we're gonna think about the forward reaction, and the stuff on the right to be the products.
So let's write our equilibrium expression. And so we write our equilibrium constant, and now we're gonna write Ka, which we call the acid ionization constant. So this is the acid ionization.
constant, or you might hear acid dissociation constant. So acid dissociation. So either one is fine. Alright, and we know when we're writing an equilibrium expression, we're gonna put the concentration of products over the concentration of reactants.
So over here for our products, we have H3O plus, let's write the concentration of hydronium, H3O plus, times the concentration of amine. A minus, so times the concentration of A minus, all over the concentration of our reactants. So we have HA over here, so we have HA, so we write that in. And then for water, we leave water out of our equilibrium expression.
It's a pure liquid, its concentration doesn't change, and so we leave H2O out of our equilibrium expression. All right, so let's use this idea of writing an ionization constant, and let's apply this. to a strong acid. HCl is gonna function as a Bronsted-Lowry acid and donate a proton to water, which is going to be our Bronsted-Lowry base.
And so we could think about a lone pair of electrons in the oxygen taking our proton, leaving those electrons behind. So the oxygen is now bonded to three hydrogens because it picked up a proton, giving this a plus one charge. And so once again, let's follow those electrons in red. So this electron pair picks up this proton to form this bond. so we form H3O plus or hydronium.
And these electrons in green move off onto the chlorine. So let's show that. So we form the chloride anion. So let me go ahead and draw in the electrons in green.
And let me go ahead and write a negative one charge here like that. So another way to represent this acid-base reaction would just be to write out H2O plus HCl gives us H3O plus plus Cl minus, so this is just a faster way of doing it. And HCl is a strong acid.
Strong acids donate protons very easily. And so we can say this process occurs 100%. So we get 100% ionization.
The equilibrium is so far to the right. that I just drew this one arrow down over here. So we get approximately 100% ionization, so everything turns into our products here.
And let's go ahead and write our equilibrium expression. So Ka is equal to... equal to concentration of H3O plus, so concentration of our products, times concentration of Cl minus. All over, we have HCl and we leave out water.
So if we think about approximately 100% ionization, we have all products here. So we have a very, very large number in the... the numerator, an extremely small number in the denominator.
So if you think about what that does for your Ka, that's gonna give you an extremely high value for your Ka. So Ka is much, much, much greater than one here. And so that's how we recognize a strong acid.
So an acid ionization constant that's much, much greater than one. Now let's think about the conjugate base. Alright, so let's go back up here. So we had HCl and Cl-as our conjugate acid-base pair.
And the stronger the acid, the weaker the conjugate base. Alright, so HCl is a strong acid, so Cl-is a weak conjugate base. So let me write that here.
So the stronger the acid, so stronger the acid, weaker the conjugate, weaker the conjugate base. And one way to think about that, is if I look at this reaction, we can think about competing base strength. So here we have Bronsted-Lowry base, water's acting as a Bronsted-Lowry base and accepting a proton. And over here, if you think about the reverse reaction, the chloride anion would be trying to pick up a proton from hydronium for the reverse reaction here. But since HCl is so good at donating protons, that means that the chloride anion is not very good at accepting them.
So the stronger the acid, the weaker the conjugate base. Water's a much better source of hydrogen. a much stronger base than the chloride anion. Finally, let's look at acetic acid.
So acetic acid is going to be our Bronsted-Lowry acid, and this is going to be the acidic proton. So water's gonna function as a Bronsted-Lowry base, and a lone pair of electrons in the oxygen is going to take this acidic proton proton, leaving these electrons behind on the oxygen. So let's go ahead and draw our products. So we would form the acetate anion.
So let me go ahead and draw in the acetate anion. So negative one charge on the oxygen. And let's show those electrons. These electrons in green move off onto the oxygen right here, giving it a negative charge.
We're also gonna form hydronium, so H3O plus. So let me go ahead and draw in hydronium, so a plus one formal charge on the oxygen. And let's show those electrons in red.
So this electron pair picks up the acidic proton, forming this bond, and we get H3O plus. So another way to write this acid-base reaction would be just to write acetic acid, CH3COOH, plus H2O, gives us the acetate anion, CH3COO-plus H3O+. Now, acetic acid is a weak acid, and weak acids don't donate...
protons very well. And so acetic acid's gonna stay mostly protonated. So when you think about this reaction coming to an equilibrium, you're gonna have a relatively high concentration of your reactants here.
So when we write the equilibrium expression, Ka is equal to the concentration of your product, so CH3COO minus times the concentration of H3O plus. plus all over the concentration of acetic acid because we leave water out. So all over the concentration of acetic acid.
The equilibrium lies to the left because acetic acid is not good at donating this proton. And so we're going to get a very large number for the denominator for this concentration. So this is a very large number and a very small number for the numerator. So this is a very small number. So if you think.
Think about what that does to the Ka. A very small number divided by a very large number. This gives you a Ka value, an ionization constant much less than one. So this value is going to be much less than one.
And that's how we recognize, it's one way to recognize a weak acid. Look at the Ka value.