“soon” can vary quite a bit, depending on what is false. Following the link, I’m skeptical of “From the study of that single pebble you could see the laws of physics and all they imply.” Specifically, I’m skeptical that one can deduce the parts of the laws of physics that matter under extreme conditions (general relativity, physics at Plank-scale energies) by examining the behavior of matter under benchtop conditions, at achievable levels of accuracy. The motivation for building instruments like the LHC in the first place is that they allow probing parts of physical laws which would otherwise produce exceeding small effects or exceedingly rare phenomena.
The tricky part is the “achievable levels of accuracy”. It would be possible for, say Galileo to invent general relativity using the orbit of mercury, probably. But from a pebble, you would need VERY precise measurements, to an absurd level.
“soon” can vary quite a bit, depending on what is false. Following the link, I’m skeptical of “From the study of that single pebble you could see the laws of physics and all they imply.” Specifically, I’m skeptical that one can deduce the parts of the laws of physics that matter under extreme conditions (general relativity, physics at Plank-scale energies) by examining the behavior of matter under benchtop conditions, at achievable levels of accuracy. The motivation for building instruments like the LHC in the first place is that they allow probing parts of physical laws which would otherwise produce exceeding small effects or exceedingly rare phenomena.
The tricky part is the “achievable levels of accuracy”. It would be possible for, say Galileo to invent general relativity using the orbit of mercury, probably. But from a pebble, you would need VERY precise measurements, to an absurd level.