DonAVP wrote:Fridger listed the four forces.
weak, electromagnetic, strong AND gravitational
What strikes me as interesting is the difference of the first three forces relative to gravity. The weak and strong forces are at the sub-atomic scale and influence small amounts of matter. Electromagnetic force influences certain types of atoms only at the outer electron shells and also has a temperature variable as it interacts with atoms. Gravity is such a different animal compared to these. It only comes into play when very very very very large numbers of atoms come together. And is a function of mass only. Yet gravity appears to be the driver at the macro scale and can over whelm the other forces (black holes). If one were to plot on a log scale with influence to size or number of atoms. I would guess that starting at the weak force through strong to electromagnetic the line would start curving up but when it gets to gravity the line goes straight up.
Don,
this is a VERY good question, indeed. Thanks for asking it. Let me try to explain in a non-technical way, why the ranges of the 4 basic forces are so different despite their common nature based on gauge theories.
There are two main ingrediens one has to know.
i) Reminiscent of Heisenberg's uncertainty principle, the range of an elementary force in distance is inversely proportional to the mass of the particle that acts as the carrier of the force, i.e.
range * mass ~ 1
(in particle physicst's units: h-bar = speed_of_light = 1)
In gauge theories, the carrier particles of the force are called "
gauge bosons":
Some names should be familiar:
Force:.......................................Carrier particle
===================================
Electromagnetic:........................Photon (massless)
Weak.................................W, Z bosons (very massive)
Strong (QCD)............................Gluons (massless)
Gravitational.............................Graviton (massless)
ii) In any gauge theory, the
occurrence of mass and thus a finite range for the force requires a subtle mechanism, since massive carriers of the gauge force are INCOMPATIBLE with the underlying gauge symmetry!
To generate mass in gauge theories in accordance with the gauge principle, there are precisely TWO alternatives:
- The so-called Higgs mechanism as taking place in Weak Interactions.
- Confinement as taking place in Strong Interactions (QCD)
Hence despite gluons being massless, the confinement of quarks and gluons within protons or pions, shortens the basically infinite range of the strong force (massless gluons!!) to the size of the proton, say. I.e. to
1 fermi = 1.0 x 10?€“15 metres = 1 femtometre
You may rephrase this by saying that due to confinement, the range of the strong force is determined by the mass of the lightest
boundstate particle of gluons and quarks, the Pion.
The range of the Weak force is becoming VERY short, since the weak gauge bosons W, Z have acquired a heavy mass due to the Higgs mechanism.
NOTE: The latter mechanism requires the existence of yet another special particle, the Higgs boson, that is the last missing link in the famous Standard Model of particle physics. The Higgs boson will hopefully be discovered soon, at the forthcoming LHC collider(CERN)!
In summary: Gauge Theories are basically theories the corresponding forces of which have
infinite range, since the gauge particles should be massless unless one of two possible mechanisms took place (Confinement or "spontaneous breakdown of the gauge symmetry" via the Higgs mechanism).
We have seen why --exceptionally-- the ranges of the weak and strong forces are VERY short, acting only within subatomic scales. In contrary, the carriers of the electromagnetic and the gravitational force (Photon and Graviton, respectively) are TRULY massless and thus the corresponding forces act on VERY LARGE distances, despite being weak in nature.
Despite these different manifestations, the structure of the underlying theories is all the same, nevertheless, i.e. we have a most beautiful and highly constrained gauge theory for all known basic forces.
NOTE: It was only noted much later that Einstein's gravity can be recast in form of a gauge theory, thus making all known interactions look similar. Of course, this lends strong weight to the possibility that at very short distances all known forces can be unified into one.
Bye Fridger
