|
THE IMPLICATIONS OF TENSOR MESH TIME DILATION So I have what may be a fairly easy way to study and prove parts of my theories. It will take NASA or another space agency to tackle but we actually have a way to help visualize the tensor mesh of space time. A web of synchronized extremely precise chronometers placed outside of our solar system and inside of our solar system if able to keep time in nanoseconds or even smaller units would see time slow down inside the areas where I predict the tensor mesh would be the strongest. With a sufficient number of these placed at strategic points where we expect strong and weak tensor strength (aggregate gravity wells). I predict we can see variations in time dilation occurring. If we can see this already with GPS satellites then we know we have a way to recognize and record the amount of the dilation. Making devices designed to track the smallest deviations in time can allow us to measure the tensor strength at all different spots outside our solar system ( may take a century or more to get to this point) and when we do this experiment I am certain it will tell us a lot more about our universe and how to interpret certain observations. Since we have an idea what the approximate mass of the remote objects are then using the time dilation measurements we can try to gauge the strength of specific parts of the localized tensor mesh and be able to trace the diminishing strength of certain objects. If we have ball park ideas how massive certain items are and how far away they are (which we do) then measuring the time dilation at all those different points can help provide the calculation that defines at what point the amplitude of gravitational waves hits plank length. It is unknown if a wave can continue past Planck length but I think that is the lowest amplitude we will ever be able to measure. What looks to us like the dissipation of energy being carried by the wave as it spreads out to create a larger and large sphere of influence continues on for greater distances than we can measure. The disturbance of spacetime equilibrium that we call electromagnetic radiation and more particularly gravity hits a point where we can no longer measure the amplitude of the waves with our most precise instruments. But the energy carried by the wave does not stop there. There continues to be a movement of energy along the wave at amplitudes we can't yet measure. But someday if we can in fact confirm the existence of the quantum foam and the approximate size of the particles at that scale factor then it will be very interesting to see if we can gauge if the intensity of wave appears to continue into even smaller scales. If we asked someone what happens as they approach the event horizon of a black hole and had 3 clocks, One clock a parsec in front of us , one clock on our body, and one clock a parsec behind us, we would expect most people to agree that the clock in front of us would perceive time differently than the clock behind us. This I feel would be no different than how the tensor mesh of space time will also cause time dilation. Using the prior analogy where the tensor mesh gave off light and it was brightest near massive objects and slowly got dimmer the farther away it got until it eventually fades to a very dim glow. Then in each point in space time where multiple tensors intersect the "brightness" ,Depth of the combined gravity well, may be proportionally brighter based on the aggregate energy at that point in spacetime. So our tensor mesh of every intersecting sphere of influence from every object inside our known universe will cause varying levels of time dilation at all different points. Areas close to huge black holes or near the great attractor will see the greatest impact but the key here is that across all of our localized pocket or relative space time its not just that every pocket of space time has its own perception of time but time itself in between galaxies could be passing at different rates. So let me try to provide a visualization. We have 4 galaxies. Galaxy Alpha and galaxy Beta each have a total mass of 2 trillion solar masses. Galaxy Omega and galaxy Psi have total masses of 20 trillion solar masses. Each are in areas of their cluster far from most other objects and separated by 100,000,000 light years. My prediction is the empty space between galaxies Omega and Psi will see a much greater time dilation than the empty space between Alpha and Beta. The implications I feel for the fact that we can have significant differences in the passage of time when looking at all different places inside our visible universe means that we might need to someday try to map out an approximate map of our tensor mesh and determine where those areas are that we may expect to see time pass slower or faster. I do not think that tensor mesh time dilation would impact red-shift and blue-shift calculations because the photons in theory do not experience time and in theory should not be impacted by passing through a slower moving area of spacetime BUT gravitational lensing does leave open the potential possibility that the strongest areas of tensor mesh strength might cause certain calculations that rely on frequency or wavelength to have a larger potential margin for error than we currently accept. But another way to think about this could be in the empty space between galaxies Omega and Psi we could see a dwarf galaxy Delta move through between the larger galaxies in its orbit. It spends 10 million years directly in the path of the strongest areas of the tensor mesh and then moves on. Most the planets inside that galaxy would have no real idea that their time is being dilated. To them all their clocks still tick away at the same rate. But as they peered outwards into the cosmos far from the objects near them what impact would their time dilation have on the observations they make against the objects outside their localized dilation? It would seem there are times where the natural state of nature sure feels a little unnatural. The other implication of tensor mesh time dilation is that in theory might provide a way to find the frequency and wavelength of gravity. If gravity in fact was some type of EM wave and we could use a web of chronometers to measure the areas of strongest and weakest impact then we could place sensor arrays in those areas to basically try a brute force hack to locate gravitational waves. I could be wrong but I don't think that the gravitational waves that LIGO is tracking are the same gravitational waves I am referring to. I could be wrong but if we have found the wavelength and frequency for gravity I would think I would have heard about it. We need to scan for wavelengths we would never normally scan for and look for very long wavelengths since we know that shorter wavelengths would carry more energy and we believe gravity is a fairly weak force but able to traverse great distances. I realize this goes against general relativity which trust me I don't take lightly but you can not just warp something like spacetime without some transference of energy and if all transference of energy happens in waves as I feel they do then gravity moves as a wave. It is either its own type of non-EM wave or its hidden and mingled inside the EM spectrum we already know about. #timedilation #tensormesh #tensormeshofspacetime Gravity Caused By Time Dilation ? #thenaturalstateofnature
All the darkness in the entire vast multiverse can not defeat the flame of a single candle.
|