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Darren New <dne### [at] san rrcom> wrote:
> Warp wrote:
> > Btw, I have never quite understood the reason why objects can't go
> > inside each other (given that objects are actually practically empty
> > space with staggeringly tiny corpuscules here and there, at relatively
> > enormous distances from each other).
> Electrons are emitting and absorbing virtual photons in huge numbers all the
> time. (It's the same thing keeping the electrons in "orbit" around the protons.)
> The photons go between the nearby electrons in your arm and in the chair,
> changing the motion of both electrons such that they do not continue getting
> closer to each other.
I didn't understand that at all.
--
- Warp
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Warp wrote:
> Darren New <dne### [at] sanrrcom> wrote:
>> Warp wrote:
>>> Btw, I have never quite understood the reason why objects can't go
>>> inside each other (given that objects are actually practically empty
>>> space with staggeringly tiny corpuscules here and there, at relatively
>>> enormous distances from each other).
>
>> Electrons are emitting and absorbing virtual photons in huge numbers all the
>> time. (It's the same thing keeping the electrons in "orbit" around the protons.)
>
>> The photons go between the nearby electrons in your arm and in the chair,
>> changing the motion of both electrons such that they do not continue getting
>> closer to each other.
>
> I didn't understand that at all.
Your ass is supported by beams of light? :-)
Basically, all electrons are constantly emitting and re-absorbing photons.
When two electrons get close enough, they start emitting photons that the
other electron absorbs. This changes the motion of the electrons such that
they won't get too close to each other.
--
Darren New, San Diego CA, USA (PST)
Serving Suggestion:
"Don't serve this any more. It's awful."
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Darren New escreveu:
> Warp wrote:
>> Darren New <dne### [at] sanrrcom> wrote:
>>> Warp wrote:
>>>> Btw, I have never quite understood the reason why objects can't go
>>>> inside each other (given that objects are actually practically empty
>>>> space with staggeringly tiny corpuscules here and there, at relatively
>>>> enormous distances from each other).
>>
>>> Electrons are emitting and absorbing virtual photons in huge numbers
>>> all the time. (It's the same thing keeping the electrons in "orbit"
>>> around the protons.)
>>
>>> The photons go between the nearby electrons in your arm and in the
>>> chair, changing the motion of both electrons such that they do not
>>> continue getting closer to each other.
>>
>> I didn't understand that at all.
>
> Your ass is supported by beams of light? :-)
I can picture Feynman saying that. :)
--
a game sig: http://tinyurl.com/d3rxz9
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Darren New <dne### [at] sanrrcom> wrote:
> Warp wrote:
> > Darren New <dne### [at] sanrrcom> wrote:
> >> Warp wrote:
> >>> Btw, I have never quite understood the reason why objects can't go
> >>> inside each other (given that objects are actually practically empty
> >>> space with staggeringly tiny corpuscules here and there, at relatively
> >>> enormous distances from each other).
> >
> >> Electrons are emitting and absorbing virtual photons in huge numbers all the
> >> time. (It's the same thing keeping the electrons in "orbit" around the protons.)
> >
> >> The photons go between the nearby electrons in your arm and in the chair,
> >> changing the motion of both electrons such that they do not continue getting
> >> closer to each other.
> >
> > I didn't understand that at all.
> Your ass is supported by beams of light? :-)
> Basically, all electrons are constantly emitting and re-absorbing photons.
> When two electrons get close enough, they start emitting photons that the
> other electron absorbs. This changes the motion of the electrons such that
> they won't get too close to each other.
I still don't quite get it. Well, I suppose I will have to submit to the
fact that I have never understood it, and I still don't understand it.
--
- Warp
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Warp wrote:
> I still don't quite get it. Well, I suppose I will have to submit to the
> fact that I have never understood it, and I still don't understand it.
Well, I'm certainly no Feynman, but you could say all the "gaps" you think
are there are actually full of photons. The photons last only a very brief
time. When the electrons from one atom are close enough to the other that
the photon has time to go between, they interact. That's really about all I
understand of it also. I'm not sure that anyone knows better the *why* of it.
--
Darren New, San Diego CA, USA (PST)
Serving Suggestion:
"Don't serve this any more. It's awful."
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Darren New <dne### [at] sanrrcom> wrote:
> Warp wrote:
> > I still don't quite get it. Well, I suppose I will have to submit to the
> > fact that I have never understood it, and I still don't understand it.
> Well, I'm certainly no Feynman, but you could say all the "gaps" you think
> are there are actually full of photons.
Does that mean that the reason why objects can't pass through each other
is fundamentally electromagnetic?
A photon is the basic unit (quantum) of electromagnetic radiation and
although it has no mass, it's also the force carrier of electromagnetic
force. But how exactly does this work in this situation? What forces are
acting what?
Additionally, photons have a frequency. If the gaps are full of photons,
what produces them. what is the frequency of these photons and why?
> The photons last only a very brief time.
Where do they disappear to, and why? Certainly their energy has to go
somewhere, it cannot simply disappear.
> When the electrons from one atom are close enough to the other that
> the photon has time to go between, they interact.
Why doesn't this happen with electrons orbiting the same atom?
If the repulsive force of the photons produced by electrons is so strong
as to completely forbid two atoms from passing through each other, why are
the electrons in one atom exempt from this same repulsion force?
--
- Warp
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Note, again, this is all my layman understanding.
Warp wrote:
> Does that mean that the reason why objects can't pass through each other
> is fundamentally electromagnetic?
Yes. There's only four forces: gravity, electomagnetic (aka electrostatic or
quantum electrodynamic), the weak force (which I think is what holds the
nucleus together) and the strong force (which I think is what holds the
quarks in a proton or neutron together). The QED force is photons
interacting with electrons, and nothing else. So, basically, anything not
gravity or "nuclear" is electromagnetic.
> A photon is the basic unit (quantum) of electromagnetic radiation and
> although it has no mass, it's also the force carrier of electromagnetic
> force. But how exactly does this work in this situation? What forces are
> acting what?
Photons and electrons interact. It makes the electrons change which
direction they're going.
> Additionally, photons have a frequency. If the gaps are full of photons,
> what produces them.
Quantum uncertainty, apparently. At this point, I'm not sure anyone knows
the "why" of spontaneous photon generation. Basically, every possible
combination of giving-off-photons and absorbing-photons is averaged together
(with the appropriate math for "averaged") and the probability that
something happens is based on that.
> what is the frequency of these photons and why?
There are apparently many frequencies. Altho, as I understand it, a photon
doesn't have an actual frequency on its own. Every photon is identical. What
gives a photon its frequency is the relative motion of the source and
destination of the photon. Otherwise relativity wouldn't work.
>> The photons last only a very brief time.
>
> Where do they disappear to, and why?
They get absorbed again. It's like saying the contact between billard balls
lasts a very brief time.
> Certainly their energy has to go
> somewhere, it cannot simply disappear.
Yes, it is imparted to the electrons. Which is what's holding your ass up in
spite of gravity. The photon pushes chair down and ass up, for a net change
of zero. :-)
The emission of the photon from an electron causes that electron to have
less energy. The absorption causes it to have more energy. Net result is zero.
Very often, photons will be emitted from an electron and almost instantly
reabsorbed by the same electron. That's where the photons come from.
Read the first instance (i.e., the #10 negative energy) of this article:
http://listverse.com/2010/11/04/10-strange-things-about-the-universe/
Essentially, vacuum isn't empty. It's constantly full of random virtual
particles that come into existence, last for a tiny amount of time, and then
annihilate each other (being equal-and-opposite). Photons do this, and
electrons do this, as far as anyone can tell from measurements. So at 10nm
distance, the two plates have excluded enough random particle possibilities
that there's an entire atmosphere of pressure on the outside more than there
is between them, just as an example of how tiny is "tiny".
>> When the electrons from one atom are close enough to the other that
>> the photon has time to go between, they interact.
>
> Why doesn't this happen with electrons orbiting the same atom?
It does. That's why all the electrons don't collapse onto the
oppositely-charged nucleus. That is the source (I think) of the Pauli
exclusion principle.
> If the repulsive force of the photons produced by electrons is so strong
> as to completely forbid two atoms from passing through each other, why are
> the electrons in one atom exempt from this same repulsion force?
Because they're also exchanging photons with the protons. The protons have
an opposite charge, which means they basically move in the opposite
direction (of how an electron would move) when they absorb or emit a photon,
and this causes the electrons to move closer to the proton instead of
farther away. So the electrons are pushing each other apart, but the protons
are pulling them closer, so the more protons, the more electrons it'll hold
onto. Then you can look at the periodic table and see how the "holes" and
"overages" of ionic behavior follow.
Alternately, and I might be misunderstanding/misremembering this, one of the
"nuclear" forces (strong or weak) might be involved here. Oh, OK, according
to wikipedia, the strong force holds protons to other protons (i.e., holds
the nucleus together) *and* holds quarks together. Weird. The weak force
apparently deals with neutrinos, beta decay, and other stuff I understand
nothing about. :-)
Basically, the nuclear forces work on essentially the same principle, except
they have different particles, different likelihoods of interaction, etc.
--
Darren New, San Diego CA, USA (PST)
Serving Suggestion:
"Don't serve this any more. It's awful."
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Darren New <dne### [at] sanrrcom> wrote:
> > If the repulsive force of the photons produced by electrons is so strong
> > as to completely forbid two atoms from passing through each other, why are
> > the electrons in one atom exempt from this same repulsion force?
> Because they're also exchanging photons with the protons. The protons have
> an opposite charge, which means they basically move in the opposite
> direction (of how an electron would move) when they absorb or emit a photon,
> and this causes the electrons to move closer to the proton instead of
> farther away. So the electrons are pushing each other apart, but the protons
> are pulling them closer, so the more protons, the more electrons it'll hold
> onto. Then you can look at the periodic table and see how the "holes" and
> "overages" of ionic behavior follow.
So this is the reason why when you shoot a lone neutron towards an object,
it will (usually) go right through as if there was nothing there (except in
the odd cases where it just happens to collide with a nucleus, as there are
quite many of them there, in which case it's deviated or even reflected),
because neutrons are electromagnetically neutral and thus don't interact
with the electrons and protons? Moreso with neutrinos, which are like
neutrons but a lot smaller (so a lot less chances of colliding with
something in there).
Btw, I don't remember now what happens if you shoot a lone proton towards
an object. As it's electrically charged, it ought to interact with the
object immediately, if I understand correctly. But what happens?
--
- Warp
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Warp wrote:
> So this is the reason why when you shoot a lone neutron towards an object,
> it will (usually) go right through as if there was nothing there (except in
> the odd cases where it just happens to collide with a nucleus, as there are
> quite many of them there, in which case it's deviated or even reflected),
> because neutrons are electromagnetically neutral and thus don't interact
> with the electrons and protons?
That's my understanding of the basics of it, yes. "Charge" is basically the
probability that any given photon will be emitted or absorbed by another
particle. A charge of "1" (plus or minus) means you have about one chance in
137 of a particular photon interacting with a particular electron at any
particular instant they meet. Nobody knows where that number comes from.
> Moreso with neutrinos, which are like
> neutrons but a lot smaller (so a lot less chances of colliding with
> something in there).
That I don't know about.
> Btw, I don't remember now what happens if you shoot a lone proton towards
> an object. As it's electrically charged, it ought to interact with the
> object immediately, if I understand correctly. But what happens?
Yes, but it's so much bigger than an electron that it can knock an electron
out of orbit (i.e., it can affect an electron with so many photons that the
electron's attraction to the electron's associated nucleus is basically
overwhelmed) without losing much of its own momentum. So it tends to go
quite some way if it's moving quickly, but with the charge it tends to stop
quickly once it slows down (compared to neutrons), in part because it'll
pick up an electron of its own, turn into a hydrogen atom, and now be much
closer to the size of other atoms instead of the size of a nucleus.
In other words, yes, it interacts with (mostly) the electrons and possibly
the protons if it happens to get close, but mostly by smashing through the
substance you're shooting them at if they're going fast. Electrons, on the
other hand, will run into other electrons and stop quickly, no matter how
fast they're going, because each interaction will on average result in two
electrons with half the momentum (and shooting off a bunch of photons in the
process, which is where you get x-ray machines and CRTs and such). A proton
is some 2000x as heavy, so it can go a lot farther before it stops.
That's why gamma radiation (high-energy photons) takes thick lead to stop,
x-rays (slightly less energetic) takes thin lead to stop, beta radiation
(high-energy electrons) takes a few millimeters of lighter metal to stop,
and alpha radiation (basically helium nuclei) takes like a piece of paper to
stop.
--
Darren New, San Diego CA, USA (PST)
Serving Suggestion:
"Don't serve this any more. It's awful."
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Darren New <dne### [at] sanrrcom> writes:
> Note, again, this is all my layman understanding.
>
> Warp wrote:
>> Does that mean that the reason why objects can't pass through each other
>> is fundamentally electromagnetic?
>
> Yes. There's only four forces: gravity, electomagnetic (aka
Freeman Dyson say no:
"A seminal work by Dyson came in 1966 when, together with Andrew Lenard
and independently of Elliott H. Lieb and Walter Thirring, he proved
rigorously that the exclusion principle plays the main role in the
stability of bulk matter.[13] Hence, it is not the electromagnetic
repulsion between electrons and nuclei that is responsible for two wood
blocks that are left on top of each other not coalescing into a single
piece, but rather it is the exclusion principle applied to electrons and
protons that generates the classical macroscopic normal force. In
condensed matter physics"
http://en.wikipedia.org/wiki/Freeman_dyson
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