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  • Hi. It's Mr. Andersen and in this video I'm going to talk about Acids,

  • Bases and pH. If you ask people what pH measures, they'll usually say if something is an acid

  • or a base. And they might know that water has a pH of 7. That acids are generally lower

  • than that and bases higher than 7. But that's where a lot of people's understanding ends.

  • And so I kind of want to explain to you what pH is and how it's determined. But before

  • that I want to tell you why it's important. And I'm a biology teacher. And so everything

  • kind of goes back to life. And so this is a protein. It's called myoglobin. It's found

  • in your muscles. And it's going to be most active at a pH of 6. It's going to work at

  • a pH of 5 all the way up to 7. But if we start to move our pH too low or too high, that protein

  • is going to denature. And our muscles aren't going to work. And so it's important that

  • the pH levels remain relatively constant and they're not changing that much. But what is

  • pH? Well we've got to start by talking about water. And so this is a water molecule. Remember

  • we're going to have hydrogen here. Two hydrogen atoms. And then one oxygen atom. Now one thing

  • that you need to understand is that this is a polar molecule. And what that means is there's

  • a covalent bond between the hydrogen and the oxygen. Between this hydrogen and oxygen as

  • well. And oxygen is really greedy when it comes to electrons. It's going to pull the

  • electrons towards it. And so this is a sharing of electron between these atoms. But it's

  • a polar covalent bond. And what that means is since oxygen is pulling the electrons towards

  • it, it's going to have partial negative charge on this side of the oxygen. And the hydrogens

  • are going to have a positive charge on the other side. And so if we were to add another

  • molecule of water, these are not going to arrange this way. In fact what we'll have

  • is they'll be arranged like that. And so the hydrogen atom of one water molecule is going

  • to be attracted to the oxygen of another. And that bond is called a hydrogen bond. A

  • lot of students think that hydrogen bond is in here, but no, that's covalent. But the

  • hydrogen bond is going to be between the positive hydrogen, partially positive. And the negative

  • oxygen. And that's why if we have one water molecule and the hydrogens are like positive

  • and the oxygens are negative. And we have another one, they're going to line up like

  • this. And as I pull one water molecule, the other one is going to go along with it. And

  • that's why we have cohesion. And it explains a lot about water. But some weird thing happens

  • with water. Sometimes that attraction is so great that this hydrogen atom will actually

  • become detached from the water and it will be come attached on to this other water molecule.

  • That would be like me pulling this pinky off and attaching it over on to this other water

  • molecule. Leaving me just with this. And so what is that called? This is called hydronium.

  • Hydronium is going to be H3O and it's going to have a positive charge. What are we left

  • with over here? This is a hydroxide ion. And so what is pH a measure of? Well the p stands,

  • we think, for the power of hydrogen. In other words the amount of hydrogen. But it could

  • also be the amount of hydronium or the amount of just free hydrogen ion inside the water.

  • And so if we look at the power of that, or almost the percentage of that, that's going

  • to be what pH measures. And in regular water, distilled water, they amount of this occurring

  • is really, really rare. In other words it's a 1 in 10,000,000 chance that we're going

  • to have hydronium. And this is really a molar concentration. So to give you a sense of the

  • scale, let's say this hydronium ion right here is represented with this little cube.

  • And so what I'm going to do is pull back. And let's say this is one cube and 10 and

  • 100 and 1000 and eventually what we get, if we scale that, you really can't see that cube

  • anymore. But this would represent 10 million cubes. And so the chances of that one hydronium

  • forming are going to be really really low. But even though the probability of hydronium

  • forming is low, it actually occurs in water and it has huge impacts on things that are

  • found within that water itself. And so that 1 in 10,000,000, I want you to think about

  • that for just a second, and let's kind of add a little bit of the equation of pH. And

  • so some kids get scared by the equation. It's not that scary. So pH or the power of hydrogen

  • is equal to the negative log of the hydrogen ion concentration. It's also the same as the

  • hydronium. That's that H3O plus. Those are essentially the same thing. So it's the negative

  • log of that. And so it's the negative log, think of this, as 1 in 10,000,000. And this

  • would actually be a molar concentration. But we're keeping it conceptual right now. And

  • so if we take the negative log of that, let's write 1 in 10,000,000 in scientific notation.

  • And so it's the negative log of one times 10 to the negative 7th. So this is going to

  • be a really small number here, and this is where the math gets really easy. If you were

  • to put this in your calculator, if we take the negative log of one times 10 to the negative

  • 7, what do we get? 7. And so the pH is going to be 7. And this gives us a number that we

  • can actually deal with. And so what does it mean if the pH is 7? It means that the concentration

  • of this hydrogen ion is going to be really, really small. And if we ever vary that, then

  • we're going to be varying the pH. And so pH of 7 is neutral. But if we ever have a value

  • greater than 7, it's going to be a base. And if it's ever lower than that then it's going

  • to be an acid. And so let's start by dealing with the acids. What's an acid that almost

  • everybody is familiar with? That's hydrochloric acid. You'd find that in your stomach. And

  • so if we add hydrochloric acid to water, it's going to disassociate. It's going to breakdown

  • into hydrogen ions and chloride ions. And so you can see here that we're increasing

  • the amount of this H+. And so what is that going to do to that concentration? Now instead

  • of being 1 in 10,000,000, it might be as often or as common as 1 in 100. And so if we were

  • to right that as scientific notation. It's the negative log of 1 times 10 to the negative

  • 2. So we would have a pH of 2. And so depending on the concentration of hydrochloric acid,

  • we could have a pH of 2 or 1 or 3. It depends on how much hydrochloric acid is in there.

  • Now let's look at a base. And so a base for example, this would be sodium hydroxide. Or

  • lye. What's going to happen to that when we add it to water? It's going to break apart

  • into sodium ions. And hydroxide ions. Now that doesn't help us. Remember, because pH

  • stands for the power of hydrogen ion. But what do you think is going to happen to that

  • hydrogen ion that happens to be in the water? Now we've got a hydrogen ion and we have a

  • hydroxide ion. And those are quickly going to combine to form water. And as it does that

  • it's going to gobble up that hydrogen ion. What's that going to do the amount of hydrogen

  • ion in the water or hydronium ion for that matter? It's going to make it even more rare.

  • And so now we have the PH equal to the negative log of 1 times 10 to the negative 12 for example.

  • And so what's that going to be? That's going to give us a pH of 12. And so what does pH

  • measure? It just measures the amount of hydrogen ions. Or hydronium ions. And bases and acids

  • are going to have different amounts of that. We measure that using a pH scale. And so distilled

  • water is going to have a pH of 7. If we have anything higher than that, that's going to

  • be a base. Anything lower than that, that's going to be an acid. But when you're taking

  • a test, it can be somewhat confusing. And so let's say we increase the amount of hydrogen

  • ions in a solution. So we're going to have more of them. What's that going to do to the

  • pH? It's actually going to lower it. And vice versa on bases. And so watch out for that

  • when you're taking a test. Why is this important? Well acid rain is one example of that. Or

  • the acidification of our oceans is another example. And so this is looking at the pH

  • in the oceans over the last couple hundred years. And what we see is that our oceans

  • are becoming more acidic. How does that work? You're combining carbon dioxide with the water.

  • And as we increase the amount of carbon dioxide in the atmosphere, that water and the carbon

  • dioxide are combining to make carbonic acid in the oceans. And that's increasing the acidity

  • of our oceans. And so we could hear, see here, the pH is decreasing. So we've seen a decrease

  • of around negative 0.1 on the pH scale over the last couple hundred years. And you might

  • think, well that's not that big of deal. But remember this is a log scale. So by decreasing

  • it by a small amount in the pH, we're going to increase it quite a bit in the hydrogen

  • ion. And that's going to effect anything living in the oceans. It could effect coral reefs.

  • And every time we have a massive extinction on our planet, it seems to be correlated with

  • the acidification of our oceans. And so that's pH. Pretty simple. And I hope that was helpful.

Hi. It's Mr. Andersen and in this video I'm going to talk about Acids,

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酸、塩基、pH (Acids, Bases, and pH)

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    Wayne Lin に公開 2021 年 01 月 14 日
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