Considering the spherical configuration right angles would not be possible and further there isn't any angular momentum integrity in the process. Your assuming right angle discharge because of a proposed set of poles but that hasn't been established and implies that the white hole is fixed within the black hole. There is validity in the compression theory being held by the gravitational strength disallowing even light to escape. If particle matter from the accretion disc is spiraling inward toward the central mass, and assuming the heat ratio is as you describe, I guess it would be possible that instead of a mass infusion of the matter within the compressed mass there would be an explosive refraction, somewhat like that of a cold drop of water on a red hot skillet only reactionary to the electromagnetic and radiation properties in play, which ultimately determine the degree of luminosity and the consistency of it. Now let's take a look at the Oreo cookie and donuts; put the coffee on mate.
On Apr 16, 10:44 am, Pat <[email protected]> wrote: > Hello All, > I was thinking about quasars this week and what they might be and > stumbled across something interesting that I thought I might share > with you. Firstly, my thought was that a quasar might just be a black > hole with a white hole at the centre. Probably NOT a new thought, but > it led me to work out what a white hole MIGHT be. I thought that, > perhaps, a white hole is an area of space that is completely filled. > But how could that happen? Well, if the pressures inside the black > hole are strong enough to compress the energy inside to the smallest > wavelength possible, that of the Planck length, then THAT would > completely fill that area of space-time with tiny, but incredibly > powerful photons. > SO, here’s some of the maths: Start with the speed of light: > 299,792,458 metres per second. Now, divide that number by the Planck > length of 1.616252^-35. That comes out to a frequency of 1.8548621^ > +49 Hz. () Now, assuming that area is a bog-standard “black body”, > it would produce a temperature of 5.3749609522385^+39 degrees Kelvin. > And THAT, my friends, is, technically, the hottest temperature > allowable in this universe and, thus, the opposite end of the Kelvin > scale. Well, at least the highest temperature one could expect to > find in THIS universe. > So, if a white hole, as described above, were to exist inside a > super-massive black hole, when any matter from the black hole’s > accretion disc fell into the black hole, it would approach the white > hole and get thrown out at right angles (i.e., the matter would spew > from the poles, as black holes are spinning) and THAT seems to fit the > observations we see of what quasars do. Any thoughts, anyone? > > -- > You received this message because you are subscribed to the Google Groups > ""Minds Eye"" group. > To post to this group, send email to [email protected]. > To unsubscribe from this group, send email to > [email protected]. > For more options, visit this group > athttp://groups.google.com/group/minds-eye?hl=en. -- You received this message because you are subscribed to the Google Groups ""Minds Eye"" group. To post to this group, send email to [email protected]. To unsubscribe from this group, send email to [email protected]. For more options, visit this group at http://groups.google.com/group/minds-eye?hl=en.
