Electrons, the nucleus and the uncertainty principle.

In summary, the uncertainty principle states that we cannot have certain knowledge about both the position and velocity of a particle. If an electron falls into the nucleus, both its position and velocity will be certain. This explanation contradicts its self, because the uncertainty principle states that we cannot have certain knowledge about either of those things.
  • #1
uranium_235
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I read somewhere that one of the explanations for an electron not spiraling into the nucleus is due to the uncertainty principle. If an electron falls into the nucleus both its position and velocity will be certain. How is that possible? Does the nucleus have both certainty in position and velocity? Then would not this explanation contradict its self?
 
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  • #2
uranium_235 said:
I read somewhere that one of the explanations for an electron not spiraling into the nucleus is due to the uncertainty principle. If an electron falls into the nucleus both its position and velocity will be certain. How is that possible? Does the nucleus have both certainty in position and velocity? Then would not this explanation contradict its self?

1. In a sketch, draw a horizontal axis as the r (radial) axis, and the vertical axis as the potential energy (U) axis.

2. Sketch the coulomb potential U=-kQq/r, where Q is the charge of the nucleus, and q is the charge of another charged particle. This is the potential relevant in a simple, hydrogenic-type atom.

3. For a bound charge particle q, it can have a substantial probability to exist confined within the potential well bounded by the vertical axis, and the U potential profile.

4.. Now look at what happens when a charge q gets closer and closer to the nucleus, i.e. as r -> 0. The particle cannot have a substantial probability anywhere else other than within the potential well. And the width of the well is getting smaller and smaller as r approaches zero, meaning we are confining the charge to smaller and smaller region of space. Consequently, we are knowing more and more about where q is radially, thus reducing the uncertainty in its position.

5. If there is no uncertainty principle, this will cause no problem. However, because it is there, there will be an increase in the range of momentum values the charge can have. This will act as a counter effect to oppose being confined to a smaller volume. Thus, there is a minimum ground state that does not allow it to be any "closer".

Zz.
 
  • #3
uranium_235 said:
... Does the nucleus have both certainty in position and velocity? Then would not this explanation contradict its self?

The mass of a particle enters into calculations of uncertainty. If the electron were replaced by a muon, which is similar but has a couple hundred times the mass of an electron, the muon would be confined pretty tightly near the nucleus. The nucleus itself is more massive yet than a muon, and so it is effectively confined to a miniscule region near the middle of an atom.

John Baez gives a nice 'back of the envelope' type of calculation here:

http://math.ucr.edu/home/baez/lengths.html
 
  • #4
Ah, I get it. I was reading bits and pieces from different sources, now they seem to come together. Thank you.
 

Related to Electrons, the nucleus and the uncertainty principle.

1. What are electrons?

Electrons are subatomic particles that carry a negative charge and are found orbiting around the nucleus of an atom.

2. What is the nucleus?

The nucleus is the central part of an atom that contains protons and neutrons. It carries a positive charge and is responsible for the stability of the atom.

3. What is the uncertainty principle?

The uncertainty principle, also known as Heisenberg's uncertainty principle, states that it is impossible to know both the exact position and momentum of a subatomic particle at the same time. This is due to the inherent nature of quantum mechanics and the limitations of measurement.

4. How do electrons contribute to the stability of an atom?

Electrons play a crucial role in the stability of an atom. They are responsible for creating chemical bonds between atoms, which results in the formation of molecules. Additionally, the arrangement of electrons in different energy levels around the nucleus determines the overall stability of an atom.

5. How do scientists study electrons and the nucleus?

Scientists use a variety of methods to study electrons and the nucleus. These include techniques such as electron microscopy, particle accelerators, and spectroscopy. These methods allow scientists to observe and manipulate subatomic particles in order to better understand their behavior and properties.

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