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Types of decay

Alpha, Beta, Gamma Decay and Positron Emission. Created by Sal Khan.

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  • aqualine ultimate style avatar for user Junwei
    wait if an atom has basically space then how do we touch objects?
    (24 votes)
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    • aqualine ultimate style avatar for user eric
      simply speaking, the electrons in your finger are pushing the electrons of the object. Think of trillions of magnets in your finger with North facing trillions of magnets in an object also facing North. The harder (closer) you push the harder the magnets push back. In fact getting two particles of the same charge close enough to "touch" would almost mean a nuclear reaction of some sort. Touching as we think about it is just electric fields pushing each other. Remember almost all matter that we can interact with is electrons on the outside and protons buried deep inside the atoms.
      (61 votes)
  • aqualine seed style avatar for user Rachel
    What exactly happens in gamma decay? After looking at some of the equations, it's clear that in alpha and beta decay, the nucleus becomes stable by forming a different one. However, with the gamma decay equations, all I see is the same nuclei, except that one has a sort of asterisk beside it and the other doesn't. Sorry if this question doesn't belong here; I'm just wondering how it works.
    (16 votes)
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    • marcimus pink style avatar for user Zach
      Gamma decay only occurs after alpha and beta decay in a sample, thats one thing to remember. Gamma decay doesn't change the mass or any other properties of the atom. Gamma rays are simply high energy photons, electromagnetic radiation. When a nucleus still has too much energy, but is done releasing alpha and beta decay particles, it will release the energy by swapping the spin of a neutron or proton and releasing a high energy photon in the process.
      (23 votes)
  • orange juice squid orange style avatar for user Ted Park
    if the elements change after decaying, does that mean that exposing some random element to radiation can create new elements as well?
    (15 votes)
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    • male robot hal style avatar for user Reinhard Grünwald
      Yes!
      That has huge practical consequences e.g. for the choice of materials for the reactor vessels of nuclear power plants. You have to make sure that the material does not change into something unwanted when exposed to intense neutron radiation (e.g. into highly radioactive elements or impurities that cause the steel to become brittle).
      (22 votes)
  • scuttlebug green style avatar for user Test Student
    So why is an electron an electron rather than a negatron? Is it because the electron was discovered before the positron and it has to do with electricity?
    (8 votes)
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    • male robot hal style avatar for user Reinhard Grünwald
      "elektron" is the greek word for amber. It was the first material which was shown to have "strange" properties when rubbed (eg it attracted things). So these phenomena were called "electric". This was long before we knew what caused these phenomena and that there was a "negative" and a "positive" "charge".
      (19 votes)
  • male robot hal style avatar for user Harsh Mehta
    We consider neutrons made of protons and electrons while explaining Beta-decay. But according to new studies protons and neutrons are made of quarks (up up down and up down down) , then why does proton and neutron have different sets of quarks i.e. what does electron do in neutron to change the configuration of neutron from protons in terms of quarks, as electron is not made of quarks? Even if electron is binded with proton in neutron it won't be able to change the quarks in proton, would it?
    (5 votes)
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    • male robot hal style avatar for user Reinhard Grünwald
      Neutrons do not consist of a proton and an electron! Neutrons are made of three quarks: two "down" (short: d) quarks and an "up" (u) quark. A "d" quark has a charge of -1/3 and an up has +2/3 which makes the neutron electrically neutral (-1/3+(-1/3)+2/3=0). In beta decay one of the "d"s is converted into a "u" and an electron is emitted in the process alongside an electron-antineutrino. In this way a new particle is created with three quarks: uud which happens to be a proton! (you can check, that it has a charge of +1)
      (21 votes)
  • leaf green style avatar for user TeraVolt
    As I was learning about radioactive decay, I came across neutron decay. I don't understand what they mean that the electron has a "spread of energies" during this decay. Can someone please how it has a spread of energies, both theoretically and mathematically? I know that this is because of the neutrino also emitted during the process, but what do they mean by "spread of energies"?
    (6 votes)
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    • male robot hal style avatar for user Reinhard Grünwald
      n --> p + e + neutrino
      In the decay process a certain (fixed) amout of energy is released and shows up in the kinetic energy of the three product particles. Since you can distribute this energy continuously between p, e and neutrino, the emitted electrons do not have a "sharp" (one single value) but a spread out energy distribution.
      To provide some more intuition, suppose there was no neutrino, but only two particles released. Then they would have to fly apart in exactly opposite direction (in the frame of reference where the neutron is at rest) and the laws of energy conservation and conservation of momentum would allow you to exactly determine their respective energies (only one value of energy for the proton and one for the electron will satisfy both conservation laws)
      (7 votes)
  • spunky sam blue style avatar for user Gururaj
    Why does the instability of an atom cause a decay?
    (3 votes)
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  • male robot hal style avatar for user Yash
    How can a proton having mass less than that of a neutron change into a neutron, releasing a positron also having some mass? How do we account for this mass difference (gain)?
    (4 votes)
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  • leaf green style avatar for user Moly
    Why a helium nucleus and not something else ? why not neon or argon nuclei emit? or why not a simple hydrogen nucleus ? it is less than helium nucleus , this one should have been emited
    (2 votes)
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  • piceratops ultimate style avatar for user singhalmanu9
    What exactly is gamma decay? It still is a bit confusing.
    (3 votes)
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    • mr pants teal style avatar for user Anthony
      Gamma decay happens when the nucleus of an atom changes it's configuration. This doesn't change the element in any way, but it does emit a large amount of electromagnetic energy. We call this type of energy a "gamma ray". Gamma ray's are similar to light rays, except that they have a very high frequency and a small wavelength (~ 10 picometers). For comparison, red-colored light has a relatively low frequency while violet-colored light has a relatively high frequency. So you can think of gamma rays as ultra-ultra-ultraviolet light (superseding UV and X-ray).
      (6 votes)

Video transcript

SAL: Everything we've been dealing with so far in our journey through chemistry has revolved around stability of electrons and where electrons would rather be in stable shells. And like all things in life, if you explore the atom a little further you'll realize that electrons are not the only stuff that's going on in an atom. That the nucleus itself has some interactions, or has some instability, that needs to be relieved in some way. That's what we'll talk a little bit about in this video. And actually the mechanics of it are well out of the scope of a first-year chemistry course, but it's good to at least know that it occurs. And one day when we study the strong nuclear force, and quantum physics, and all the like, then we can start talking about exactly why these protons and neutrons, and their constituent quarks are interacting the way they do. But with that said, let's at least think about the different types of ways that a nucleus can essentially decay. So let's say I have a bunch of protons. I'll just draw a couple here. Some protons there, and I'll draw some neutrons. And I'll draw them in a neutral-ish color. Maybe let me see, like a grayish would be good. So let me just draw some neutrons here. How many protons do I have? I have 1, 2, 3, 4, 5, 6, 7, 8. I'll do 1, 2, 3, 4, 5, 6, 7, 8, 9 neutrons. And so let's say this is the nucleus of our atom. And remember-- and this is, you know, in the very first video I made about the atom-- the nucleus, if you actually were to draw an actual atom-- and it's actually very hard to drawn an atom because it has no well-defined boundaries. The electron really could be, you know, at any given moment, it could be anywhere. But if you were to say, OK, where is 90% of the time the electron is going to be in? You'd say, that's the radius, or that's the diameter of our atom. We learned in that very first video that the nucleus is almost an infinitesimal portion of the volume of this sphere where the electron will be 90% of the time. And the neat takeaway there was that, well, most of whatever we look at in life is just open free space. All of this is just open space. But I just want to repeat that because that little infinitesimal spot that we talked about before, where even though it's a very small part of the fraction of the volume of an atom-- it's actually almost all of its mass-- that's what I'm zooming out to this point here. These aren't atoms, these aren't electrons. We're zoomed into the nucleus. And so it turns out that sometimes the nucleus is a little bit unstable, and it wants to get to a more stable configuration. We're not going to go into the mechanics of exactly what defines an unstable nucleus and all that. But in order to get into a more unstable nucleus, sometimes it emits what's called an alpha particle, or this is called alpha decay. Alpha decay. And it emits an alpha particle, which sounds very fancy. It's just a collection of neutrons and protons. So an alpha particle is two neutrons and two protons. So maybe these guys, they just didn't feel like they'd fit in just right, so they're a collection right here. And they get emitted. They leave the nucleus. So let's just think what happens to an atom when something like that happens. So let's just say I have some random element, I'll just call it element E. Let's say it has p, protons. Actually let me do it in the color of my protons. It has p, protons. And then it has its atomic mass number, is the number of protons plus the number of neutrons. And do the neutrons in gray, right? So when it experiences alpha decay, what happens to the element? Well, its protons are going to decrease by two. So its protons are going to be p minus 2. And then its neutrons are also going to decrease by two. So its mass number's going to decrease by four. So up here you'll have p minus 2, plus our neutrons minus 2, so we're going to have minus 4. So your mass is going to decrease by four, and you're actually going to turn to a new element. Remember, your elements were defined by the number of protons. So in this alpha decay, when you're losing two neutrons and two protons, but especially the protons are going to make you into a different element. So if we call this element 1, I'm just going to call it, we're going to be a different element now, element 2. And if you think about what's generated, we're emitting something that has two protons, and it has two neutrons. So that its mass is going to be the mass of the two protons and two neutrons. So what are we emitting? We're emitting something that has a mass of four. So if you look at, what is two protons and two neutrons? I actually don't have the periodic table on my [? head. ?] I forgot to cut and paste it before this video. But it doesn't take you long on the periodic table to find an element that has two protons, and that's helium. It actually has an atomic mass of four. So this is actually a helium nucleus that gets emitted with alpha decay. This is actually a helium nucleus. And because it's a helium nucleus and it has no electrons to bounce off its two protons, this would be a helium ion. So essentially it has no electrons. It has two protons so it has a plus 2 charge. So an alpha particle is really just a helium ion, a plus 2 charged helium ion that is spontaneously emitted by a nucleus just to get to a more stable state. Now that's one type of decay. Let's explore the other ones. So let me draw another nucleus here. I'll draw some neutrons. I'll just draw some protons. So it turns out sometimes that a neutron doesn't feel comfortable with itself. It looks at what the protons do on a daily basis and says, you know what? For some reason when I look into my heart, I feel like I really should be a proton. If I were a proton, the entire nucleus would be a little bit more stable. And so what it does is, to become a proton-- remember, a neutron has neutral charge. So what it does is, it emits an electron. And I know you're saying, Sal, you know, that's crazy, I didn't even know neutrons had electrons in them, and all of that. And I agree with you. It is crazy. And one day we'll study all of what exists inside of the nucleus. But let's just say that it can emit an electron. So this emits an electron. And we signify that with its-- roughly its mass is zero. We know an electron really doesn't have a zero mass, but we're talking about atomic mass units. If the proton is one, an electron is 1/1,836 of that. So we just round it. We say it has a mass of zero. Its mass really isn't zero. And its charge is minus 1. It's atomic, you can kind of say its atomic number's minus 1. So it emits an electron. And by emitting an electron, instead of being neutral, now it turns into a proton. And so this is called beta decay. And a beta particle is really just that emitted electron. So let's go back to our little case of an element. It has some number of protons, and then it has some number of neutrons. So you have the protons and the neutrons, then you get your mass number. When it experiences beta decay, what happens? Well, are the protons changed? Sure, we have one more proton than we had before. Because our neutron changed into one. So now our protons are plus 1. Has our mass number changed? Well let's see. The neutrons goes down by one but your protons go up to by one. So your mass number will not change. So it's still going to be p plus N. so your mass stays the same, unlike the situation with alpha decay, but your element changes. Your number of protons changes. So now, once again, you're dealing with a new element in beta decay. Now, let's say we have the other situation. Let's say we have a situation where one of these protons looks at the neutrons and says, you know what? I see how they live. It's very appealing to me. I think I would fit in better, and our community of particles within the nucleus would be happier if I too were a neutron. We'd all be in a more stable condition. So what they do is, that little uncomfortable proton has some probability of emitting-- and now this is a new idea to you-- a positron, not a proton. It emits a positron. And what's a positron? It's something that has the exact same mass as an electron. So it's 1/1836 of the mass of a proton. But we just write a zero there because in atomic mass units it's pretty close to zero. But it has a positive charge. And it's a little confusing, because they'll still write e there. Whenever I see an e, I think an electron. But no, they say e because it's kind of like the same type of particle, but instead of having a negative charge, it has a positive charge. This is a positron. And now we're starting to get kind of exotic with the types of particles and stuff we're dealing with. But this does happen. And if you have a proton that emits this particle, that pretty much had all of its positive charge going with it, this proton turns into a neutron. And that is called positron emission. Positron emission is usually pretty easy to figure out what it is, because they call it positron emission. So if we start with the same E, it has a certain number of protons, and a certain number of neutrons. What's the new element going to be? Well it's going to lose a proton. p minus 1. And that's going to be turned into a neutron. So p is going to go down by one. N is going to go up by one. So that the mass of the whole atom isn't going to change. So it's going to be p plus N. But we're still going to have a different element, right? When we had beta decay, we increased the number of protons. So we went, kind of, to the right in the periodic table or we increased our, well, you get the idea. When we do positron emission, we decreased our number of protons. And actually I should write that here in both of these reactions. So this is the positron emission, and I'm left over with one positron. And in our beta decay, I'm left over with one electron. They're written the exact same way. You know this is an electron because it's a minus 1 charge. You know this is a positron because it has a plus 1 charge. Now there's one last type of decay that you should know about. But it doesn't change the number of protons or neutrons in a nucleus. But it just releases a ton of energy, or sometimes, you know, a high-energy proton. And that's called gamma decay. And gamma decay means that these guys just reconfigure themselves. Maybe they get a little bit closer. And by doing that they release energy in the form of a very high wavelength electromagnetic wave. Which is essentially a gamma, you could either call it a gamma particle or gamma ray. And it's very high energy. Gamma rays are something you don't want to be around. They're very likely to maybe kill you. Everything we did, I've said is a little theoretical. Let's do some actual problems, and figure out what type of decay we're dealing with. So here I have 7-beryllium where seven is its atomic mass. And I have it being converted to 7-lithium So what's going on here? My beryllium, my nuclear mass is staying the same, but I'm going from four protons to three protons. So I'm reducing my number of protons. My overall mass hasn't changed. So it's definitely not alpha decay. Alpha decay was, you know, you're releasing a whole helium from the nucleus. So what am I releasing? I'm kind of releasing one positive charge, or I'm releasing a positron. And actually I have this here in this equation. This is a positron. So this type of decay of 7-beryllium to 7-lithium is positron emission. Fair enough. Now let's look at the next one. We have uranium-238 decaying to thorium-234. And we see that the atomic mass is decreasing by 4, minus 4, and you see that your atomic numbers decrease, or your protons are decreasing, by 2. So you must be releasing, essentially, something that has an atomic mass of four, and a atomic number of two, or a helium. So this is alpha decay. So this right here is an alpha particle. And this is an example of alpha decay. Now you're probably saying, hey Sal, wait, something weird is happening here. Because if I just go from 92 protons to 90 protons, I still have my 92 electrons out here. So wouldn't I now have a minus 2 charge? And even better, this helium I'm releasing, it doesn't have any electrons with it. It's just a helium nucleus. So doesn't that have a plus 2 charge? And if you said that, you would be absolutely correct. But the reality is that right when this decay happens, this thorium, it has no reason to hold on to those two electrons, so those two electrons disappear and thorium becomes neutral again. And this helium, likewise, it is very quick. It really wants two electrons to get stable, so it's very quick to grab two electrons out of wherever it's bumping into, and so that becomes stable. So you could write it either way. Now let's do another one. So here I have iodine. Let's see what's happening. My mass is not changing. So I must just have protons turning into neutrons or neutrons turning into protons. And I see here that I have 53 protons, and now I have 54 protons. So a neutron must have turned into a proton. A neutron must have gone to a proton. And the way that a neutron goes to a proton is by releasing an electron. And we see that in this reaction right here. An electron has been released. And so this is beta decay. This is a beta particle. And that same logic holds. You're like, hey wait, I just went from 53 to 54 protons. Now that I have this extra proton, won't I have a positive charge here? Well you would. But very quickly this might-- probably won't get these exact electrons, there's so many electrons running around-- but it'll grab some electrons from some place to get stable, and then it'll be stable again. But you're completely right in thinking, hey, wouldn't it be an ion for some small amount of time? Now let's do one more. So we have to 222-radon-- it has atomic number of 86-- going to 218-polonium, with atomic number of 84. And this actually is an interesting aside. Polonium is named after Poland, because Marie Curie, she-- At the time Poland, this was at the turn of the last century, around the end of the 1800's, Poland didn't exist as a separate country. It was split between Prussia, Russia, and Austria. And they really wanted let people know that, hey, you know, we think we're one people. So they discovered that when, you know, radon decayed it formed this element. And they named it after their motherland, after Poland. It's the privileges of discovering new elements. But anyway, back to the problem. So what happened? Our atomic mass went down by four. Our atomic number went down by two. Once again, we must have released a helium particle. A helium nucleus, something that has an atomic mass of four, and an atomic number of two. And so there we are. So this is alpha decay. We could write this as a helium nucleus. So it has no electrons. We could even say immediately that this would have a negative charge, but then it loses