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Particles for all forces: how do they know where to go, and what to avoid?
Here's an intuitive problem which I can't get around, can someone please explain it?
Consider a proton P and an electron E moving through the electromagnetic field (or other particles for other forces, same argument). They exert a force upon one another. In classical mechanics this is expressed as their contributing to the field and the field exerts a force back upon them in turn. In quantum mechanics the model is the exchange of a particle.
Let's say one such particle X is emitted from P and heads towards E. In the basic scenario, E absorbs it and changes its momentum accordingly. Fine.
How does X know where E is going to be by the time it arrives? What's to stop E dodging it, or having some other particle intercept X en route?
Are P and E emitting a constant stream of force-carrying particles towards every other non-force-carrying particle in the universe? Doesn't this imply a vast amount of radiation all over the place?
I am tempted to shrug of the entire particle exchange as a mere numerical convenience; a discretization of the Maxwell equations perhaps. I am reluctant to say "virtual particle" because I suspect that term means something different to what I think it means.
Or is it a kind of observer effect: E "observes" X in the act of absorbing it, all non-intercepting paths have zero probability when the waveform collapses?
Or have I missed the point entirely?
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2 Answers By Expert Tutors
Rick R. answered • 07/31/19
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Electrical engineering specialist, MSEE degree, EE practitioner
Particles are described in quantum mechanics by wave functions that permeate throughout all of space and time. This description includes not only matter and anti-matter particles (fermions), such as electrons, but also force-carrying particles (bosons), such as photons. The interaction between the fermions and the bosons is mediated by the interaction between their respective wave functions.
Carlos B. answered • 03/16/19
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Bacherlor of science in physics
Think for example of a laser. It is emitting photons in a straight beam and if something is on the way of it, the atoms from the target material are going to absorb this photons, but no one is telling this photons where to go to meet some E particle. They are just following the most straight line. And in fact there is a lot of radiation coming from everywhere onto you. Not only photons but also neutrinos and some other of particles are going trough you body every second, also mostly every kind of material is a little radioactive all the time. The wave function collapses when a measure is realized to the traveling photon, so this implies an interaction with some other atom, which causes that the measured value becomes the state of the particle with probability equals to one. So every other "path" (measure value) get's 0 of probability when that happens.
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Kristopher G.
The particles have no energy, and so yes there are a number of particles going in all directions all the time. They cover a certain surface area and as the distance doubles the surface area goes up by radius squared so that’s why we have inverse square law for electromagnetism. Gravity is better described by a curvature of space time. Rather than virtual particles. The photon and graviton (if it exists is massless). The intermediating particles of the strong and week force are massive therefore they can only exist a short amount of time who is why those forces have limited range. I have a few degrees in physics but will admit quantum physics isn’t my strongest suit07/02/19