The discussion centers on the exact cause of radioactive decay, emphasizing that it is a spontaneous process where unstable atomic nuclei break into more stable fragments. Participants assert that while decay rates can be described probabilistically, the specific timing of decay events is fundamentally random and cannot be attributed to a deterministic cause. Key decay mechanisms include alpha decay via the tunneling effect, beta decay through weak interactions, and gamma decay through electromagnetic interactions. Ultimately, the consensus is that no definitive cause exists for why a particular atom decays at a specific moment.
PREREQUISITESPhysicists, students of quantum mechanics, and anyone interested in the fundamental principles of radioactive decay and the nature of randomness in the universe.
Yes I know, but its probability doesn't address its cause.Vanadium 50 said:It's probabilistic.
The way you are asking still gives just 'probability'. What you really want is, just the first part of what you ask: WHY DECAY?Darwin said:Yes I know, but its probability doesn't address its cause.
What I'm looking for is the "why," not the likelihood of its appearance. Why does a decay event happen when it does and not at some other time?
Darwin said:exactly what is it that causes an atom to decay at a particular time rather than at some other time?
The cause of radioactive decays depend on the specific decay. E.g., ##\alpha## decay is due to the tunneling effect (Gamow-theory of ##\alpha## decay), ##\beta## decay is due to the weak interaction, and ##\gamma## decay is due to the electromagnetic one.Darwin said:Summary:: The EXACT cause of a radioactive decay event
I recognize that radioactive decay is a spontaneous process in which an unstable atomic nucleus breaks into smaller, more stable fragments, but exactly what is it that causes an atom to decay at a particular time rather than at some other time?
And that's what I'm trying to ferret out. If what you say is true then radioactive decay is truly an event that has absolutely no cause. It could just as well never happen as happen. An unstable atomic nucleus may never lose energy by radiation. In fact, trillions upon trillions of unstable atomic nuclei may be in the process of existing forever. I know this probably comes across as an exaggeration, but if you're correct then it would seem this remains as a distinct possibility.Vanadium 50 said:You're asking for something that doesn't exist. It is truly random and not deterministic.
Darwin said:So I guess my difficulty is science's leap to an extremely farfetched reason, uncaused randomness, which has never shown up in any other aspect of existence.
While you say the cause of an atomic nucleus emitting an alpha particle is the tunneling effect, it's been my understanding that tunneling can only take place after the decay event. Am I wrong? If I am, then there must be some component within the tunneling effect that determines the "when" of the decay event.vanhees71 said:The cause of radioactive decays depend on the specific decay. E.g., ##\alpha## decay is due to the tunneling effect (Gamow-theory of ##\alpha## decay), ##\beta## decay is due to the weak interaction, and ##\gamma## decay is due to the electromagnetic one.
The lifetime of any specific nucleus is in all these cases random due to quantum mechanics. So there is no cause that a specific nucleus decays at the specific time you observe it to do so, i.e., there's some probability that the nucleus decays within a given time (measured from the time you estabished it to be there). It's given approximately by ##P(t)=1-\exp(-\lambda t)##.
As you see, only for a stable nucleus, where ##\lambda=0## you are certain that it never decays. That's the case if the nucleus is an exact energy eigenstate of the complete Hamiltonian.
Aside from supposed uncaused atomic decay do you know of any other event in the universe that is uncaused (undetermined)? If so, please share.PeroK said:It's the clockwork determinism of classical physics that I find far fetched! Apart from a few simple cases, where was there ever any evidence for that?
Thank you.Vanadium 50 said:I can only tell you what the answer is. I can't make you like it.
Randomness occurs on at least two levels:Darwin said:Aside from supposed uncaused atomic decay do you know of any other event in the universe that is uncaused? If so, please share.
Darwin said:it's been my understanding that tunneling can only take place after the decay event. Am I wrong?
Darwin said:Aside from supposed uncaused atomic decay do you know of any other event in the universe that is uncaused (undetermined)?
Dynamical systems that are expressed by chaos theory are more than theoretically deterministic, but actually deterministic, even those we commonly call random. And unpredictability has no bearing on the deterministic nature of an event. All unpredictability does is announce our inability to assess the factors that bear on its creation.PeroK said:Randomness occurs on at least two levels:
All QM phenomena, not just decay, are random. Scattering, atomic photon emission etc.
Leaving aside QM, we have classical chaos theory. Although theoretically deterministic, classical systems of sufficiently complexity (i.e. all but the simplest, stable systems) are so depending on initial conditions that their behaviour is random and unpredictable. For example: turbulence, stock market behaviour, spread of diseases, sporting events etc. In many cases, to predict a system's state beyond a short time would require initial conditions to a precision that take you into the realm of QM.
The theory is deterministic but then is it a good model for the system? If a system can be described poorly by a deterministic theory and better by a statistical theory, why ultimately prefer the deterministic one? Unless you have an a priori belief that nature must be deterministic.Darwin said:Dynamical systems that are expressed by chaos theory are more than theoretically deterministic, but actually deterministic, even those we commonly call random. And unpredictability has no bearing on the deterministic nature of an event. All unpredictability does is announce our inability to access the factors that bear on its creation.
Predictability and unpredictability are a non-factors in causation/determinism.
Not sure what you have in mind by "The theory is deterministic," but the thing is, statistical theories, nice as they may be, don't tackle the functional "whys" of an event. And, other than the possibility of uncaused subatomic events, everything else in the universe is determined (has a cause). However, as I asked before, if you know of some other event in the universe that is uncaused (undetermined), please share.PeroK said:The theory is deterministic but then is it a good model for the system? If a system can be described poorly by a deterministic theory and better by a statistical theory, why ultimately prefer the deterministic one? Unless you have an a priori belief that nature must be deterministic.
Thank you for clearing this up.PeterDonis said:Yes. The tunneling is the decay event. "Tunneling" and "decay event" aren't two separate events; they are two different ways of describing the same event.
And I think probabilities are just about everywhere, if one cares to put events into that format. What is the probability that I'll be in bed before 10 PM tonight? From past practices I put it at about 0.01%PeroK said:@Darwin PS I think my point is this: I genuinely never saw QM probabilities as the "bolt from the blue" that you do. I've always seen probabilities everywhere.
Darwin said:Not sure what you have in mind by "The theory is deterministic,"
Darwin said:statistical theories, nice as they may be, don't tackle the functional "whys" of an event.
Darwin said:as I asked before, if you know of some other event in the universe that is uncaused (undetermined), please share.
The reason that, as others pointed out, one can not predict the particular time a given nucleus will decay is that the world is quantum mechanical. In a deterministic world, given enough precise data about the state of a nucleus at a given time, one could predict when it would decay (maybe not in practice, but in theory). It is because of quantum physics that we cannot.Darwin said:Summary:: The EXACT cause of a radioactive decay event
I recognize that radioactive decay is a spontaneous process in which an unstable atomic nucleus breaks into smaller, more stable fragments, but exactly what is it that causes an atom to decay at a particular time rather than at some other time?
You've evidently dropped a significant word here or added an unnecessary one because at it stands your sentence isn't making sense.PeterDonis said:He means that the theory is a model, and a model is not the same as the thing being modeled. The fact that classical mechanics is a deterministic theory does not mean the real world that classical mechanics provides a model of must be deterministic.
If there isn't one then how does an event come into being?You're assuming that there has to be some "functional why". What if there isn't one?
No problem with possibilities if they're meaningful to the issue, which isn't the case with establishing the reason an event (other than a quantum event) arises.You might not like such a possibility, but it is a possibility.
Sorry, I was referring to events other than those of a quantum nature. This shift in subject came about when PeroK said "Leaving aside QM, we have classical chaos theory. . . ." in post 15 and started talking about "deterministic, classical systems."Both @PeroK and I have already answered this, in posts #15 and #17.
Thank you for your input.nrqed said:The reason that, as others pointed out, one can not predict the particular time a given nucleus will decay is that the world is quantum mechanical. In a deterministic world, given enough precise data about the state of a nucleus at a given time, one could predict when it would decay (maybe not in practice, but in theory). It is because of quantum physics that we cannot.
The understanding of the ##\alpha## decay in terms of Gamow's theory is that in a nucleus ##\alpha##-particles are preformed due to strong correlations in the nuclear many-body system and that these ##\alpha## particles tunnel through the barrier. Given the quite simplistic approach the corresponding prediction for the lifetime is quantitatively not too bad.Darwin said:While you say the cause of an atomic nucleus emitting an alpha particle is the tunneling effect, it's been my understanding that tunneling can only take place after the decay event. Am I wrong? If I am, then there must be some component within the tunneling effect that determines the "when" of the decay event.
Darwin said:You've evidently dropped a significant word here or added an unnecessary one because at it stands your sentence isn't making sense.
Darwin said:If there isn't one then how does an event come into being?
Darwin said:I was referring to events other than those of a quantum nature.
If the universe isn't deterministic on the classical mechanic scale then what is it? What governs its day-to-day operation?PeterDonis said:The fact that one particular model of the universe (classical physics) is deterministic does not mean the actual, real universe must be deterministic.
"It just does" is hardly persuasive.If randomness is fundamental, it just does.
But the quantum nature of the event would never rise to the level where it would affect causation in the classical mechanic world. As Mark Tegmark, physicist, cosmologist, and professor at the Massachusetts Institute of Technology said in regard to quantum events affecting neural functions of the brain,According to QM, all events have "a quantum nature". The quantum nature just isn't practically detectable in all cases. But it's always there.