I hope that readers here are starting to see how my new electricity ticks all of the boxes.
Yes, the G-string result has parallels with your theory (which is why I posted it).
I see some inconsistency in your descriptions. If an electon has difficulty clinging to an extremely mild curve in a G-line, then what makes some happily navigate a sharp 90 deg bend? "if it duznt detach" isn't an answer, it is a question.
A 180 deg u-turn around a wire of radius R (ie at a sharp bend in the wire) would be more drastic for an electon than a 90 deg turn along a radius of R (ie to follow the surface of a 90 deg sharp bend in a wire)(depending on the exact 3D geometry of the u-turn or bend).
Actually i reckon that microscopic grooves & scratches etc would be critical.
Painting enamel on the wire to slow the electons to 2c/3 (to reduce the % escaping at bends) seems to be logical.
But i reckon that they should have used fatter wire, to reduce the crowding of the electons, ie to reduce the repulsions that give a concentration of (negatively charged) electons on the outside of their (slight) bends. Perhaps they explain why they use thin wires. It might be so that they can more easily tighten the wire to reduce their (slight) bends.
Also you posited that electons are photons which travel (primarily?) on the outside of conductors, because EM travels at ~10m/s in copper if I got that right. In which case, your "reflexion" description describes surface electons either progressing around the corner or radiating away, but inner electons always reflect (at 10m/s).
Electons hug the outside of a wire, whilst propagating at the speed of light.
But electons can hug the surfaces of voids inside a wire if the wire is porous (if the electon has somehow managed to enter the wire, ie from its natural location on the outside surface of the wire). In which case for sure the internal electon might be slowed by whatever it is that slows em radiation, especially if the void is very narrow.
Electons might be able to reflect in certain situations, ie like an ordinary free photon. But i reckon that electons don’t reflect at bends in a wire or at loads (resistances) in a wire, electons do u-turns, or what i mean is that the surface does a u-turn (electons go straight ahead as usual). When i say straight ahead i need to add that electons being negatively charged can be guided somewhat by outside influences (by electric fields). And i suppose by magnetic fields, i havnt thought about that (i will have to have a think).
If em radiation is called electromagnetic radiation then perhaps i should call electric fields electro fields. Yes, i might do that from now on.
How do you explain a reflection of spacetime ("its the surface that has done the u-turn") if you deny 'Einsteinian' time contraction?
All of Einstein's Relativity is rubbish. His spacetime is rubbish (actually i don’t think that he believed in spacetime either).
But i don’t see how Einsteinian time dilation rears its ugly head in old electricity. Or in reflexion.
Maybe your theory does tick all of the boxes (I'm not implying I think it does), but what it is also doing is adding mystery, like why electons roam around on the surfaces of battery plates while sitting in the shop, not slowly, but at the speed of light. That is an awful lot of activity for something which appears for all intents and purposes to be static, again the question is not whether they do (in the theory they do), but why they should want to - a good reason for being, beyond being an option which seems to make sense to some people in certain settings (our complaint over the Poynting vector).
Electons are photons. All photons propagate at the speed of light. They can do no other.
Electons roam the surface of the negative battery terminal, in effect for ever, they don’t suffer any energy loss (i think).
What this ticked box adds to human 'knowledge' is a question. Each postulate also exists without quantified links to reality (measurement). By that I mean the numerical behaviour which explains (accurately) things like how many electons peel off the wire under defined circumstances. In time this would achieve predictive power beyond being a rough mental crutch to help think through physics situations. In spite of all this box ticking, the mystery quotient is increasing in an unbounded way.
I don’t think that we have any good info re when electons peel off a G-string wire & when they don’t.
If u want a prediction, then how about my prediction that electricity goes slower when a wire has a screw thread on its surface. This is explained by electons having to propagate further up'n'down over the threads.
If u want a numerical postdiction, then how about when a capacitor is discharged the discharge has half of the theoretical voltage for twice the theoretical time. This is explained by my electons roaming all of the surfaces. Electons going away (ie a half of all of the electons) have to do a u-turn to come back. Hence half the voltage for twice the time. What better proof (or at least confirmation) for my electons would anyone want.
For all its deep mystery (which equates to perhaps an inability to tick a box), conventional electricity theory does make good 'reasons for being' for nearly everything (electrons drift because of electric field and carry potential energy around, skin effect results from inductance and resistance). It also ties all this behaviour together with extremely robust predictive capability which works to "umpteen decimals" (much more accurate than you seem to think), being formulated in terms of mathematics more than thoughts. In that respect its inventors went for the jugular, being all hopped up on science, as was the fashion of the day. It perhaps lacked some imagination.
To that end, continuing on from my earlier post about Popper falsifiability, a good ideal to shoot for might be for half your ideas to fail: Much less, could mean you are either being too unimaginative, or testing too little (or combination).
Old electricity fails in so many ways.
I already mentioned that it is 100% out for predicting the discharge voltage of a capacitor.
I already mentioned that it is 100% out for predicting the discharge time for a capacitor.
I already mentioned that it is 50% out for predicting the speed of electricity along an enamelled wire.
But i don’t agree re ideas failing, i reckon that every box has to be ticked, one strike & new electricity is out.
But perhaps it would not be out.
After all, old electricity (electron drift) has been around since electrons were discovered or invented in 1897, & it fails to tick many boxes, but has been handy anyhow.
So, if new electricity fails to tick a box then we could still use it or parts of it until something better comes along. Thats the way it has always been & ever will be.
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