Radioactivity and Quantum Zeno Question

Join the discussion
Ask a follow-up here, or get your own question answered by working scientists, mathematicians and engineers — people, not an autocomplete.
Real named experts · corrections over time · the nuance an AI answer skips
3 replies · 2K views
musik132
Messages
11
Reaction score
0
Radioactivity is independent of the time the radioactive element was produced.
If i remember correctly (which is a big IF, correct me if I'm wrong) this has to do with the collapse of the wavefunction into a definite state by "measurements" and then slipping back into a wave to evolve again with determinism by the Schrödinger equation. Future measurements would find the particle is decayed or not with a certain probability.

Quantum Zeno effect has been observed in that repeated "measurements" are able to slow decay of various excited states.

So if we have a large dense lump of some radioactive isotope how does decay rate or its lifetime not depend on the amount of stuff in it. Wouldn't macroscopic section be able to "measure" (I'm using the quotes since I'm not entirely sure what constitutes as measurements) other sections repeatedly as to make that section not decay or slow it down. Density would also come into play by making the "measurements" more frequent I guess right?
 
Physics news on Phys.org
Hmmm, I wonder what it means exactly by distinguishable quantum states.

Is this that divide between quantum systems and classical systems because there are some relatively large systems that behave quantum mechanically. And these relatively large system of radioactive isotopes would show some correlation to delayed decay if we were able to measure such small changes in decay time right?

Sorry, I am not that far in my understanding in QM so can anyone explain when or how something becomes non distinguishable as you keep adding things to a system. The system does become more complex as you add more particles but does that make it indistinguishable or are we just unable to discern the differences.
 
For the quantum Zeno effect to work, the measurement must be sufficiently fast. More precisely, the time of measurement must be much shorter than 1/Delta H (where I use units hbar=1 and Delta H is the uncertainty of energy in the unstable state).

In most cases Delta H is large enough (and density small enough) so that the quantum Zeno effect does not work.