Do particles have discrete energy levels?

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Discussion Overview

The discussion revolves around whether particles have discrete energy levels, exploring the implications of mass on energy level separation and the nature of energy states in different contexts, including atomic and solid-state physics. Participants consider both theoretical and conceptual aspects of the topic.

Discussion Character

  • Exploratory
  • Debate/contested
  • Technical explanation

Main Points Raised

  • One participant suggests that all matter may have discrete energy levels, proposing that as mass increases, the separation of energy levels decreases, leading to a perception of continuity at larger scales.
  • Another participant counters this by referencing conduction and valence bands in metals, semiconductors, and insulators, arguing that these do not exhibit discrete energy levels.
  • A different participant supports the existence of discrete energy levels in conduction bands, explaining that they arise from a potential well with periodic boundary conditions, leading to a finite number of states below a certain energy.
  • One participant expresses uncertainty about their initial thought and seeks clarification on whether it should be neglected or if there is some truth to it.
  • Another participant emphasizes the importance of understanding existing theories and suggests that there is likely some truth to the initial thought, while also encouraging further learning about electron orbitals.
  • A later reply discusses the distinction between discrete quantum states and continuous states for free particles, noting that while free electrons can have continuous energy transitions, bound electrons in atoms have discrete spectra due to spatial confinement.
  • An analogy involving a vibrating violin string is presented to illustrate the concept of standing waves and their relation to energy levels.

Areas of Agreement / Disagreement

Participants express differing views on the existence and nature of discrete energy levels, with some supporting the idea while others contest it. The discussion remains unresolved, with multiple competing perspectives presented.

Contextual Notes

Participants reference various theories and concepts, including the quantum of action and the role of Planck's constant, but there are limitations in the assumptions made about the applicability of these concepts across different scales and contexts.

Dammes
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Im wondering if all matter have discrete energy levels because electron and nuclei have discrete energy level. my thought is that as mass increases the separation of the energy levels decease, so because mass is so large at our scale the separation of energy levels is so infinitely small and see it as a continuous scale?
Tell me if my way of thinking is completely wrong, its just a thought.
 
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Have you never heard of the conduction and valence bands of metals, semiconductors, and insulators? There are no "discrete" energy levels there.

Zz.
 
@ZapperZ
Of course there are - the conduction band of a metal in the usual treatment comes about from a potential well with periodic b.c.s, with discrete spacing. That's why you can have a density of states - if the levels were truly continuous, you could cram as many electrons as you want into any small energy interval. Without a finite number of states below a certain energy, things like a fermi sphere could not exist.

We can treat the levels as quasi-continuous just because there are so many of them and because they are so close to each other that the distance between two adjacent levels is extremely small.
 
@ZapperZ
No i have not heard of the conduction and valence bands of metals, semiconductors, and insulators.
This is only a thought and was asking if my way of thinking is completely wrong and if I should neglect this thought.

So I'll ask this again. should I neglect this thought or is there some truth behind it?
 
Dammes said:
@ZapperZ
No i have not heard of the conduction and valence bands of metals, semiconductors, and insulators.
This is only a thought and was asking if my way of thinking is completely wrong and if I should neglect this thought.

So I'll ask this again. should I neglect this thought or is there some truth behind it?

There is probably a grain of truth to any statement. You would be well served to learn more from existing theory, as ZapperZ suggests, before you randomly speculate with non-specific conjecture.

Theory and experiment go hand in hand, there is plenty written on the rules about electron orbitals in an atom. Check out those. :smile:
 
Wikipedia has a decent, short explanation:

..Quantized energy levels result from the relation between a particle's energy and its wavelength. For a confined particle such as an electron in an atom, the wave function has the form of standing waves. Only stationary states with energies corresponding to integral numbers of wavelengths can exist; for other states the waves interfere destructively, resulting in zero probability density.

One basic distinction between discrete quantum theory and continuous relativity is the 'quantum of action' or Planck's constant, h, a cornerstone of quantum theory, that pops up in many situations...but not in relativity.

http://en.wikipedia.org/wiki/Planck_constant
 
Last edited:
should I neglect this thought or is there some truth behind it?

it's ok as a start...as stuff gets bigger and bigger the relative size of 'discrete' interactions generally loses significance. A next step to think about energy levels is along these lines:

A truly free electron has an interaction potential that is not spatially localized, so there is a continuous spectrum of states; that means the electron can interact with photons of any energy. There is no "h" involved. Such an idealized free particle can have continuous energy transitions.

In the real world there are no completely "free" particles; every particle interacts with something, so there are always some degrees of freedom present beyond the "free particle" ones. An electron bound in an atom has a spatially confined interaction potential, so its spectrum of states is discrete; that means the electron can only interact with photons that have the right energy to kick it from one of the discrete states to another..."h" is important.

A decent analogy: consider a vibrating violin string...certain frequencies resonate...these are like 'standing waves' of electrons in the Wikipedia description I gave in the prior post. Remove the fixed ends and tension...the darn string won't vibrate! In fact this analogy works ok for string theory, too, where 'particles' are extended two dimensional 'strings'...and increased tension correlates with increased particle mass.
 

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