So, getting particles down to near-0 kelvin seems impossible due to Heisenberg uncertainty of the electrons... Just pointing this out because you can't get infinity if your divisor refuses to reach 0. Or, could we measure the Kelvin measurement at 0 if we could measure it while zooming by at near-c?
Haven't decided if I'm serious about this question, because I keep getting different answers when I ask myself.
With temperature being defined as molecular motion, and motion being a change in position over some period of time, moving at light speed would have the relativistic effect of time stopping for whatever the speeding entity observes. And if time does not pass, there can be no motion. So from that reference point, everything passed by would be at absolute zero,
frozen in time. The challenge then becomes how each of those reference frames could interact with one another while maintaining light speed.
Edit: Dividing by zero as it relates to slices of pie:If I have 1 pie, and divide it by 8, I get 0.125 of the pie per slice. Dividing that pie by 10, and I get 0.1 units of pie per slice, approaching no pie at all per slice when it is divided into infinite slices. In fact, far before splitting a pie into infinite slices, there would only be quarks, electrons, muons, and bits like that per "slice". And it would be a bit of a stretch to call anything without at least 1 in tact sugar molecule a piece of a pie.
But by decreasing the denominator, dividing the pie by 1/2 gives us 2 pies. Which is a bit odd. Kind of a different question really once the denominator becomes smaller than 1. Instead of "how many units of pie do we get per x slices?", the question becomes, "how much pie would there have to be somewhere for this pie to be x slices of pie?" Imagining 1 pie to be 1/2 a slice of pie makes sense when you consider Doug. Doug will eat a whole pie in 1 sitting, from the middle out, and then go back for more. So perhaps servings is better than slices.
So while decreasing the denominator from 1 to 0, the question is, "how much pie would there have to be for this 1 pie in front of us to be x servings?" 1 ÷ 1/4 gives us 4 pies for 1 pie to only be 1/4 of a serving. 1 ÷ 0.01 would require 100 pies for that 1 pie to be 0.01 of a serving. As the denominator approaches 0, we need more and more pie. Enough pie to fill the entire galaxy at a certain point. But what happens at 0? When 1 pie is 0 servings of pie. Is there no longer any pie at all? Or does everything have to become pie? Zero in terms of units of pie refers to absolutely no pie at all. So it seems like if 1 pie is exactly 0 servings of pie, then that would define the pie as not being a pie. 1 pie = absence of pie. That doesn't make sense. Pie is pie. The flavor and type of pie is secondary here. It could be apple pie, cherry pie, or strawberry rhubarb. So we're left with the other option, that everything would have to become pie.
I'm well over my head at this point, and not sure I can continue with the analogy.
But if all things everywhere were composed 100% of pie, then 1 pie out of the infinite expanse of space and time would be inconsequential. Something would have to not be a pie in order for "pie" to have any meaning. Literally all of the ingredients of the pie would have to be pies. We would have an infinite fractal of pies spiraling all the way down such that even quarks become pie.
So it does seem to break down when we consider dividing by 0. At least in the sense of the observable universe maintaining the current laws of physics. Not that we really know what quarks and muons are anyway. Maybe they are pies? Cobblers?
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