A lot of times people do not understand the effects something can have and after we see these effects, we wonder how did we ever miss the importance of what layed underneath this process in Physics.
Richard Feynman-Dancing With Neutrinos-Nova
Much as we looked at the stars above, the views became much clearer with hubble and such, that we see the depth is necessary as we quantum dynamically learn to see with a greater comprehension.
481 MeV muon neutrino (MC) produces 394 MeV muon which later decays at rest into 52 MeV electron. The ring fit to the muon is outlined. Fuzzy electron ring is seen in yellow-green in lower right corner. This is perspective projection with 110 degrees opening angle, looking from a corner of the Super-Kamiokande detector (not from the event vertex). Option -show_non_hit was used to show all PMTs. Color corresponds to time PMT was hit by Cerenkov photon from the ring. Color scale is time from 830 to 1816 ns with 15.9 ns step. The time window was widened from default to clearly show the muon decay electron in different color. In the charge weighted time histogram to the right two peaks are clearly seen, one from the muon, and second one from the delayed electron from the muon decay. Size of PMT corresponds to amount of light seen by the PMT. PMTs are drawn as a flat squares even though in reality they look more like huge flattened golden light bulbs.
Now it is important to me that when I seen the relationships of physics extolling itself in nature, I wanted to understand how this evidence came to be. But, before I lay what nature has shown me, I wanted to explain a little further what I am starting put together in my head, about what has become common in our understanding, was not easily so from a theoretical/concept/idea standpoint. That it was indeed "progressive/reductionistic" as our views became ever more progressive as we see the same picture of the cosmo(astrophysics) in an ever widening view of understanding.
The neutrino detector for the Super-Kamiokande experiment in Japan contains ultrapure water surrounded by an array of thousands of photo-tubes, arranged to catch the flashes of light from neutrino interactions in the water. In 1998, researchers at "Super-K" found evidence for a small mass for neutrinos coming to earth from particle interactions in cosmic rays. If neutrinos, until recently thought to be massless, actually do have a mass, the implications will be profound, not only for particle physics but for astronomy and cosmology. At right is the MINOS collaboration at the Department of Energy’s Fermilab, before a slice of the 10,000-ton detector they will build to capture neutrino interactions. The MINOS experiment will use beams of accelerator-produced neutrinos by Fermilab's Tevatron to investigate neutrino mass.
Now the lesson above is quite simplistic in the sense that what was once held in theoretical views could/would have made it's way into the depths of how we see things now in nature. So in having understood that process, I wanted to show two more that you might be interested in?
Astronaut's view of the Aurora Australis, or southern lights, from aboard Space Shuttle Discovery 1991 (Courtesy: NASA)
The picture below here is what I see from my backyard when mist and rain has fallen.
So here you have it. A couple of views of nature that have been exemplifed in our search for understanding. What does this all reveal to you? Well, that's the continung saga of what the depth of perception has endowed all us human beings, as we look ever deeper into the nature of the cosmo, and the beginning of this universe.
While we had been given the Sun to look at in one of it's diverse ways, I wanted and did show that meeting the views of how we look at things. That it had been extended, by understanding the "valuation of the energy" as it has ensued from the very heart of what that burning sun is. How we gain immediate results, not ony in the particle showers, but of what evidence we have lain before us, as the physical outcome, as we look from space, and how, we look from earth.
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