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  • Hi. It's Mr. Andersen and this AP Physics essentials video 3. It is on the Atomic Nucleus

  • which was discovered by this man, Ernest Rutherford. JJ Thompson had already discovered the electron

  • which they knew had a negative charge. But they had viewed the atom as a plum pudding.

  • And this is what plum pudding looks like. It is got little plums in it. And then it

  • has got the pudding portion. So they thought the atom looked like this. It was this amorphous

  • positive charge inside the atom and then these little negative charges were interspersed.

  • And so what Rutherford did is he shot alpha particles at it. Those have a positive charge.

  • So he assumed they would just go right through since there was no positive centering of that

  • positive charge, that they would just kind of move through in a straight line. But what

  • he found is that these positive charges went straight on through but occasionally would

  • come shooting right back at him. It would be bent in some form. And so he said it was

  • like shooting a shell at a kleenex and that shell just came shooting back at him. And

  • so what he discovered was this really dense tightly packed positive nucleus which we know

  • now is made up of positive protons but also these neutral neutrons. Now the protons are

  • important because the number of protons tell us what the element is. In other words if

  • it has six protons we know that it is going to be carbon. If it has one proton then we

  • know it is going to be hydrogen. Now you can have something that is the same element, but

  • varying amounts of neutrons. And so if we add up the number of protons and neutrons

  • and they are different in a given element we call those isotopes of that element. And

  • so for example carbon 12 is going to have 6 protons. So is carbon 14 because they are

  • both carbon. But carbon 12 is going to have 6 additional neutrons and carbon 14 is going

  • to have 8 additional neutrons. And so we are going to have these different isotopes. And

  • we will find that for all of the different elements. Some of these are radioactive. And

  • what that means is they are unstable and they have a potential to decay or to fall apart.

  • They give off radiation when they do that. And the rate at which they do that is known

  • has their half-life. And so again the atomic nucleus is made up of two subatomic particles.

  • We call those protons, which have a positive charge and neutrons which have no charge.

  • You could count the number of positive charges right here and figure out what the element

  • is. If we organize the protons in a certain fashion we get the periodic table. And so

  • we know that hydrogen has 1 proton. That is what the atomic number means. We know that

  • iron has 26. We know that gold has 79. It tells us what the element is. But you can

  • have atoms of the same element and varying numbers of neutrons. And when we do that we

  • create something called an isotope. And so if we look low on the periodic table we find

  • uranium 92. That means it has 92 protons. But there are going to be three naturally

  • occurring isotopes on our planet. Uranium 238 is going to have 146 neutrons. Uranium

  • 235 will have 143. And Uranium 234 will have 142. Where did I come up with those numbers?

  • If I take 238, which is the sum of neutrons and protons and I subtract 92 that tells me

  • the number of neutrons. And so on our planet we are going to have varying amounts of that.

  • And the average of that gives us the average atomic mass. Now if we look at this graph

  • right here, this is graphing the number of protons along the x-axis and the number of

  • neutrons along the y-axis. And so this would be that virtual straight line, if the number

  • of protons and the number of neutrons are equal. And you will find right here the average

  • which is this jaggy line right here starts to drift towards the neutron side. What does

  • that mean? As our atoms get larger and larger and larger and as our atomic nucleus gets

  • larger and larger and larger, you have to have more neutrons to maintain the stability

  • of the atomic nucleus. And we will talk about that in later videos. But what you are create

  • and what the colors on this graph are are different types of decay or isotopes breaking

  • down or they are giving off what is called radiation. And so radioactive decay is when

  • the atomic nuclei breaks down. And we could summarize that in three different types of

  • radiation. You have an alpha particle and that is two protons and two neutrons that

  • are given off. You could get a beta particle. And that is either going to be an electron

  • or a positron. And then you have this high energy high level gamma radiation. It is electromagnetic

  • radiation. So this would be an alpha particle given off by a nucleus. And so it becomes

  • a different element. And so if we talk about an example of that, uranium 238 naturally

  • occurs on our planet. But it is going to undergo decay. It will lose an alpha particle. And

  • so as it loses that it is losing four of these nucleons, these parts inside the nucleus.

  • And so you can see that the mass number has changed. But it has also become a new element.

  • Since you have lost two of these protons it is not uranium anymore it is thorium. It could

  • undergo then beta decay so we lose a beta particle. And it becomes protactinium 234.

  • It could lose another beta particle and it could become uranium 234. And so each of these

  • have a probability of occurring and that probability is going to be in the atom itself. And so

  • if we take a sample of 238, we can create a curve of what is called its half-life, which

  • is the ability (or time) for half of the atoms in that sample to decay or to breakdown. And

  • so if we look at uranium 238 at the beginning of time, so time is graphed along the x-axis.

  • At time 0 we are going to have 100 percent of that uranium 238. In one half-life, that

  • is what this 1 on the x-axis stands for we are going to have 50 percent of that uranium

  • 238 decay. We are going to lose those alpha particles. Now what is the half-life of uranium

  • 238? It is a ridiculously large number. It is 4.5 billion years which is about the same

  • age as our planet. And so we would expect in that first 4.5 billion years we are going

  • to have half of that uranium 238 decay. And then the next 4.5 billion years we will go

  • from 50 percent to 25 percent. And then to 12.5. And it will keep following that at a

  • known rate because there is a known probability of each of these atoms decaying during that

  • period of time. Now what is cool about this is scientists can find a sample of uranium

  • 238. We could figure out how much of it has decayed. And we could find it along this line

  • and that would tell us how long ago that uranium 238, let's say a rock for example, had actually

  • formed. And so did you learn to describe how the internal structure of a nucleus or an

  • atomic nucleus relates to the properties of that atom? Remember the protons tell us what

  • it is and if we add the protons and neutrons we get the isotopes which can be stable or

  • unstable and can breakdown over time. And I hope that was helpful.

Hi. It's Mr. Andersen and this AP Physics essentials video 3. It is on the Atomic Nucleus

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原子核 (Atomic Nucleus)

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    Bravo001 に公開 2021 年 01 月 14 日
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