Fig. 2. Image showing how an 8 TeV black hole might look in the ATLAS detector (with the caveat that there are still uncertainties in the theoretical calculations).
The question I would pose to those who do not have the dynamical nature of the universe in mind, are you happy with what you are seeing? Is it enough that your measure will be in the value of Steven Weinberg's first three minutes?
Becuase I have taken you down to the microseconds, we can now see of this uiverse, do you think it so unlikely that the very methods for blackhole dyamics would not have include thermodynamic realizations held in context of the issue brought forward by the introduction by Paul of the Conformal Field theory and the issues relate to Penrose?
Of course I jump ahead, based on the current knowledge base I have been able to put together by reading, sharing ideas and learning. So "you see," and "I see" what?
Gamma ray detection is just the beginning of the lesson behind deeper perceptions of our universe and it is in this way that you are taken to view the universe on a much more dynamical level.
But wait, I don't talk lightly of Planck scale and the measure of the square box.
Nature (also called the material world, the material universe, the natural world, and the natural universe) is all matter and energy, especially in its essential form. Nature is the subject of scientific study. In scale, "nature" includes everything from the universal to the subatomic. This includes all things animal, plant, and mineral; all natural resources and events (hurricanes, tornadoes, earthquakes)....en.wikipedia.org/wiki/Nature
On to the Validity of the LHC
I encounter a concept the other day that took me back some. If we intercede and experiment to find the fundamental working associated with "dynamcial thinking" then how could one actually do this, while holding a "cosmological view" to all that we are exposed too in the space, around earth, and beyond?
So of course, while we are being treated to the vast views given to us by Hubble and all the satellites, how much more could we have been satisfied to say, "look at what we have accomplished?"
That is enough for the cosmologist is it not?
In physics, natural units are physical units of measurement defined in terms of universal physical constants in such a manner that some chosen physical constants take on the numerical value of one when expressed in terms of a particular set of natural units. Natural units are intended to elegantly simplify particular algebraic expressions appearing in physical law or to normalize some chosen physical quantities that are properties of universal elementary particles and that may be reasonably believed to be constant. However, what may be believed and forced to be constant in one system of natural units can very well be allowed or even assumed to vary in another natural unit system. Natural units are natural because the origin of their definition comes only from properties of nature and not from any human construct. Planck units are often, without qualification, called "natural units" but are only one system of natural units among other systems. Planck units might be considered unique in that the set of units are not based on properties of any prototype, object, or particle but are based only on properties of free space.
So as strange as it may seem "this concept" held in mind argues the validity of the LHC as a process that is "natural" as it is used to delve into the energies that allow us to see this "cascade of nature as particle manifestations. In this way, we have to support our views on what?
So, we develope instruments to help us look to the very beginnings of creation? We talk about blackholes and we ask, "are these real?"
Microstate Blackholes
What gave us the ability to entertain such concepts that we again ask ourselves, "are these real?" All we had known is that Blackholes exist in nature? So the point I am making is that if you follow the natural costants, what use the microstate in, or as a valuation of what is real in cosmological association?
If, as some suspect, the Universe contains invisible, extra dimensions, then cosmic rays that hit the atmosphere will produce tiny black holes. These black holes should be numerous enough for the observatory to detect, say Jonathan Feng and Alfred Shapere of the Massachusetts Institute of Technology in Cambridge, Massachusetts.
Fortunately while we were being occupied by the news of LHC and all the workers found busy there constructing, there were others who were very busy too. They were helping us see in ways that we were not accustom as well, in regards too, the cosmic particle collisions. Now what use this information if we had thought this avenue not fruitful and necessary?
Nevertheless, astroparticle and collider experiments should provide useful input to the theoretical work in this area. Indeed, the signatures are expected to be spectacular, with very high multiplicity events and a large fraction of the beam energy converted into transverse energy, mostly in the form of quarks/gluons (jets) and leptons, with a production rate at the LHC rising as high as 1 Hz. An example of what a typical black-hole event would look like in the ATLAS detector is shown in figure 2.
If mini black holes can be produced in high-energy particle interactions, they may first be observed in high-energy cosmic-ray neutrino interactions in the atmosphere. Jonathan Feng of the University of California at Irvine and MIT, and Alfred Shapere of the University of Kentucky have calculated that the Auger cosmic-ray observatory, which will combine a 6000 km2 extended air-shower array backed up by fluorescence detectors trained on the sky, could record tens to hundreds of showers from black holes before the LHC turns on in 2007.
Lest the knowledge doesn't serve us then what will be the quest of LHC? What new route to be taken? And it is in this design of measure that we will see something more direct to the basis of what these energy valuations serve?
CLIC is based on a novel technology in which an intense low-energy electron beam is used to generate an electromagnetic wave that is used to push a lower-intensity beam to much higher energies in a relatively small distance. It seems to be the only realistic chance of colliding electrons and positrons at multi-TeV energies so, if it works, it will allay (at least for a while) some of David Gross's concerns about the prospects for future big physics projects-John Ellis
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