How small can the quantum world get?

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Discussion Overview

The discussion revolves around the concept of the quantum world and its potential size in relation to the observable universe. Participants explore ideas stemming from string theory, the Planck scale, and the symmetry observed in nature, questioning how small the quantum realm can be and how it might relate to the larger universe.

Discussion Character

  • Exploratory
  • Conceptual clarification
  • Debate/contested

Main Points Raised

  • Some participants propose that the quantum world might be symmetrically as small as the universe is large, suggesting a relationship between the size of the universe and the quantum scale.
  • Others argue that the quantum world breaks down at the Planck level, where spacetime becomes distorted, indicating a limit to how small we can conceptualize the quantum realm.
  • One participant emphasizes that strings have not been experimentally verified and questions the status of quarks as discovered entities, highlighting the ongoing nature of scientific inquiry.
  • Another participant clarifies the hierarchical structure of matter, noting that while strings may be fundamental, they do not constitute quarks but rather are identified with them.
  • A later reply suggests that there may be a relationship between Planck units and the overall structure of the universe, proposing that the Planck mass, length, and time could correlate with cosmic scales.
  • Some participants reflect on the concept of quantum foam and its potential structural similarities to the large-scale structure of the universe, raising questions about dimensionality and scale.

Areas of Agreement / Disagreement

Participants express a range of views, with no consensus on the relationship between the quantum world and the universe's size. Some agree on the intriguing nature of symmetry, while others emphasize the limitations imposed by current understanding of quantum mechanics and string theory.

Contextual Notes

The discussion includes various assumptions about the nature of quantum mechanics, string theory, and the definitions of fundamental particles. There are unresolved mathematical and conceptual steps regarding the implications of Planck units and their relationship to the universe.

MalusIgnis
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Hey all,

I just watched a show on string theory on PBS and I thought it was so fascinating!
It got me to thinking...

First we discover molecules, then atoms, then protons and electrons, then quarks, then these strings...

Maybe, since the universe has so many instances of symmetry in the natural world... both the normal world we inhabit and the quantum world are as big. Meaning, however large the outside world is, the quantum world will be symmetrically just as small.

Say, the end of the universe is 10^47m in every direction (just a guess)... why wouldn't the quantum world be also 10^-47m?


I don't know if that has any merit, but I just wanted to see what you guys think. =)
 
Physics news on Phys.org
Well, I'm not sure off of the top of my head, but I'm pretty sure the quantum world breaks down at the Planck level. As you saw in the Popularization of SST on NOVA, at the Planck level, spacetime becomes distorted.
Paden Roder
 
Strings have not been discovered. I'm not sure we can convincingly say that quarks have been discovered, just that some experiments have been carried out consistent with theory, and no experiments have contradicted the theory. When all aspects of particle behaviour that could rationally disprove quarks have been probed, then we can say quarks are discovered. For strings, there has been no experimental verification of previously unobserved phenomena, nor is there likely to be for a very long time.

Observation raises questions; questions inspire theories, theories provoke experimentation, experimentation yields observation.

Assuming string theory is correct, and assuming experiments can be done to verify it someday, we might well observe more in those experiments than we set out to see. Those additional observations tend to spawn the next generation of new ideas.

Njorl
 
Originally posted by MalusIgnis
First we discover molecules, then atoms, then protons and electrons, then quarks, then these strings...

I want to make a small comment here, to avoid confusion: atoms make up molecules, protons and electrons make up atoms, and quarks make up protons, but strings do not make up quarks, they are quarks (and leptons, such as electrons).
 
Quark to Quark Measure

http://superstringtheory.com/forum/extraboard/messages12/726.html

Dickt said: The reason I cn't comment on all this is that you have collected good stuff from different areas, and the point is how they link together to you. You had an illustration showing what they mean by a spacelike slice of simultaneous points in spacetime, and another I think showing Randall-Sundrum gravity spreading in the bulk (but I'm not sure because I couldn't read the fine print). And some statements that I couldn't interpret.<p>The spacelike slice, which is much used by the LQG people, survives, you don't have to adopt Einstein's view if it's too difficult. Same with R-S brane and bulk, if it suits you to think of them with substance go ahead. Just remember that there are people with a more abstract view.

Well most certainly there will be generalizations, but they will be based on the mathematics. Yet if people cannot see what it is they are doing mathematically, it won't make much sense?

All one has to do is think of Susskind when he was at the blackboard
working the equation. He saw this wriggling form in place of the math, much like kaluza saw the cylinder. The math must be able to describ what he was seeing?

Sol
 
Last edited by a moderator:
Originally posted by MalusIgnis
Hey all,

I just watched a show on string theory on PBS and I thought it was so fascinating!
It got me to thinking...

First we discover molecules, then atoms, then protons and electrons, then quarks, then these strings...

Maybe, since the universe has so many instances of symmetry in the natural world... both the normal world we inhabit and the quantum world are as big. Meaning, however large the outside world is, the quantum world will be symmetrically just as small.

Say, the end of the universe is 10^47m in every direction (just a guess)... why wouldn't the quantum world be also 10^-47m?


I don't know if that has any merit, but I just wanted to see what you guys think. =)

This question Re: How small can the quantum world get?

Should actually be rephrased and equivalent in scale to this question;How accurate do you have to be in explaining the Precision needed to Understand Stringtheory?..namely:

1)Very
2)Nearly
3)Fairly
4)Precise
5)No accuracy needed at all
6)Within Mathematical accepted numbers
 
Last edited:
MalusIgnis said:
Hey all,

I just watched a show on string theory on PBS and I thought it was so fascinating!
It got me to thinking...

First we discover molecules, then atoms, then protons and electrons, then quarks, then these strings...

Maybe, since the universe has so many instances of symmetry in the natural world... both the normal world we inhabit and the quantum world are as big. Meaning, however large the outside world is, the quantum world will be symmetrically just as small.

Say, the end of the universe is 10^47m in every direction (just a guess)... why wouldn't the quantum world be also 10^-47m?


I don't know if that has any merit, but I just wanted to see what you guys think. =)


Personally, I think you are on to something. I don't know if anyone else will agree. But just consider the quantum foam, and then consider the large scale structure of clouds of galaxies. If you could freeze an instant of quantum foam, wouldn't it look very similar in structure to the large scale structure, which is described as a kind of foam in which the galaxies occur in walls with huge empty voids between them? But that's just motivation.

Consider that the Planck mass has to be some fraction of the mass of the universe. Consider that the Planck length has to be some fraction of the distance across the universe. Consider that the Planck time has to be some fraction of the age of the universe. Since there has to be a relation between Planck time, space, and mass, why should we be surprised to find that there is a similar relationship between the mass, size, and time of the Universe?

I know there is no fixed size to the universe, even if you define universe. Consider DSR, in which the constants c, Pl and Pt are not necessarily constants at all. Consider the idea of a curled dimension. Is size scale a dimension? I should think so. Is it surprizing that the largest dimensions of our universe are curled? You start at the smallest scale with quantum foam and end at the largest scale with galactic foam. Should it be surprizing that we human observers are half way from largest to smallest, half way from the beginning to the end of the universe, halfway from one side of the universe to the other? Infinite curl in expansions that are taking place in every dimension.
 

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