Understanding the Repulsive Strong Force and its Role in Nucleons and Quarks

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Discussion Overview

The discussion revolves around the nature of the strong force, particularly its role in binding nucleons within atomic nuclei and quarks within nucleons. Participants explore the apparent contradiction of the strong force being described as repulsive below 1.5 femtometres while also being responsible for attractive interactions at shorter ranges. The conversation includes theoretical considerations and models related to the strong force and its effective counterpart.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • One participant questions the notion that the strong force should be repulsive at distances less than 1.5 femtometres, given its role in holding quarks together within nucleons.
  • Another participant suggests that the strong force is weaker at very short ranges but not necessarily repulsive.
  • A distinction is made between the fundamental strong force, which binds quarks into protons and neutrons, and the effective strong force, which binds nucleons into nuclei.
  • Some participants compare the effective strong force to van der Waals forces, indicating a conceptual analogy to help visualize the interactions.
  • Models of the effective nuclear force that incorporate short-range repulsion are noted to fit experimental data better than purely attractive models, though this does not definitively imply the existence of a repulsive core.
  • There is acknowledgment that the inclusion of repulsive features in models of nucleon-nucleon interactions may improve data fitting, but the necessity of such features remains uncertain.

Areas of Agreement / Disagreement

Participants express differing views on the nature of the strong force, particularly regarding its repulsive characteristics at short ranges. There is no consensus on whether the strong force is fundamentally repulsive or if it can be effectively modeled without such assumptions.

Contextual Notes

Participants note that the discussion involves complex theoretical models and that the understanding of the strong force may depend on specific definitions and contexts. The relationship between the fundamental and effective strong forces is not fully resolved, and assumptions about repulsion at short distances are still under debate.

JZR
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Hi,

I have been taught at school that the strong force is responsible for holding the nucleons together in the nucleus but becomes repulsive below about 1.5 femtometres. I now read that the strong force is also responsible for holding the quarks together inside the nucleons, although the diameter of a proton or neutron is less than 1.5fm so surely the strong force should be repulsive not attractive?

Can someone please explain what is really happening?
 
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I see this is your first post.
Until you establish yourself around here don't be surprised if you don't get many responses.
You will get more responses once you establish that you are really here to learn and not just stir up trouble and controversy.
until then you would probably be better off asking more conventional questions first.
 
I have been taught at school that the strong force is responsible for holding the nucleons together in the nucleus but becomes repulsive below about 1.5 femtometres.
This doesn't sound right. It is weaker at very short ranges, but not repulsive.
 
The confusion is between the fundamental strong force between quarks and the effective strong force between hadrons.
 
What is the difference between the fundamental strong force and effective strong force?
 
To vastly oversimplify, the fundamental strong force is the force gluing the quarks together into neutrons and protons. The effective strong force is a remnant of this interaction that can bind neutrons and protons together into nuclei. I've seen the effective strong force compared to the van der Waals forces between molecules, if that helps you visualize it. Both protons and neutrons are uncharged (neutral) under the fundamental strong force.

Wikipedia calls the "fundamental strong force" the "strong interaction" and the "effective strong force" the "nuclear force":
http://en.wikipedia.org/wiki/Strong_interaction
http://en.wikipedia.org/wiki/Nuclear_force

PS. bcrowell wrote a nice explanation of the force between nucleons here.
 
Last edited:
Thank you, I think i will have to wait until i can do a degree in physics to fully comprehend it all

Is there any truth in what I was taught at school about the strong force being repulsive below 1.5fm? I think the reason our teachers gave us was that it was to prevent the nucleus collapsing in on itself.
 
I was too slow in adding to my previous post a link to a nice explanation of this issue by bcrowell. To summarize it very briefly, models of the "effective nuclear force" that include short-range repulsion tend to fit the data better than those that are purely attractive. However, the fact that nuclei don't collapse does not imply that there must be such a "repulsive core".
 
daschaich said:
I was too slow in adding to my previous post a link to a nice explanation of this issue by bcrowell. To summarize it very briefly, models of the "effective nuclear force" that include short-range repulsion tend to fit the data better than those that are purely attractive. However, the fact that nuclei don't collapse does not imply that there must be such a "repulsive core".

Yes. Here's the last part of that post for those that don't want to read.

"Relatively sophisticated models of the nucleon-nucleon interaction do usually include repulsion under certain circumstances, e.g., there may be a "hard core" in the potential at short ranges. The fact that all such models seem to do a better job of reproducing certain data when the repulsive features are turned on suggests that this repulsive feature is model-independent. "

What this says to me, is that repulsive features in models SOMETIMES work better than those without. And vice versa. I guess it's still up in the air.
 

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