Scientists might have spotted another universe sitting next to our own

Astronomers might have just spotted another universe, sitting right next to ours, it is considered as one of the greatest discoveries of 2015, and could change everything we know about Space, the universe and astrophysics forever.

According to astronomers, light spotted in outer space might have ‘spilled through’ from another universe very close to our own. The bright patches could be in fact leftovers from another universe that began in the vicinity of our own according to scientific study.

Thanks to a new ‘glow’ spotted in space, researchers believe another universe exists and the light we have seen might have come from that universe, outside of our own. The cosmological multiverse theory has been proposed nearly a century ago and includes the concept of ‘bubble universes’ which interact with each other, clashing ever since the Big Bang, revealing in plain sight, a visible ‘footprint’ of one another.

Scientists believe that they can actually get a peek at one if the said universe started out close enough to our universe, so the two were able to ‘touch’ which would then leave a viewable signature in our universe. In order to find these signatures, scientists have compared a map of the cosmic microwave background (which are basically leftovers from the early universe) with a picture of the entire sky taken by the European Space Agency’s Planck telescope. What they found after left researchers mesmerized. After they subtracted one from the other, they saw an eerie patch of light in the sky, a patch of light that could be explained as being the remains of collisions with other universes.

This incredible fading – reported by Dr. Ranga-Ram Chary in a study called ‘Spectral Variations of the Sky: Constraints on Alternate Universes‘ as reported by New Scientist – demonstrate that the said universe would have to have an entirely different makeup to outs.

The microwaves studied by Dr. Chary were once considered as simple electromagnetic noise, but Chary believes they are the key to sustaining the theory and that parallel universes must be very different from ours. He believes that in another universe subatomic particles, baptized as baryons and photons, with a size ten times greater than what we see in our universe exist, making the physics of that universe totally different from ours.

Chary believes that our universe could be a small region “in a super-region that inflates forever … beyond our observable universe, existing in such a way that each region would be governed by a different set of physical parameters”.

Chary concludes his paper writing: “The CMB power spectrum extracted from the Planck frequency maps has been shown to be consistent with a ΛCDM cosmology with a specific set of cosmological parameters measured with unprecedented sensitivity (Planck Collaboration et al. 2015). Much of this consistency arises from precise measurements of the power spectrum on angular scales smaller than 1◦. Why these parameters are the values they are is a question that doesn’t have a clear answer. One possibility is there is an infinite set of Universes with different parameters and our Universe just happens to have the values that we measure. Searching for these alternate Universes is a challenge. One hypothesis suggests that as each Universe evolves independently, it may collide with our observable Universe, leaving a signature on the signal we see. Since the CMB intensity has been shown to be isotropic, it is clear that such a collision is not seen in the intensity of the photons. Probing the density of baryons during the epoch of recombination, however, provides an alternate approach. If the baryon density is higher in these alternate Universes, recombination between baryons at redshift of > 1000 can leave signatures of Hydrogen recombination line emission which are redshifted into the Planck bandpasses at 143 and 353 GHz”

Why these parameters are the values they are is a question that doesn’t have a clear answer. One possibility is there are an infinite set of Universes with different parameters and our Universe just happens to have the values that we measure. Searching for these alternate Universes is a challenge. One hypothesis suggests that as each Universe evolves independently, it may collide with our observable Universe, leaving a signature on the signal we see. Since the CMB intensity has been shown to be isotropic, it is clear that such a collision is not seen in the intensity of the photons. Probing the density of baryons during the epoch of recombination, however, provides an alternate approach. If the baryon density is higher in these alternate Universes, recombination between baryons at redshift of > 1000 can leave signatures of Hydrogen recombination line emission which are redshifted into the Planck bandpasses at 143 and 353 GHz”

Probing the density of baryons during the epoch of recombination, however, provides an alternate approach. If the baryon density is higher in these alternate Universes, recombination between baryons at redshift of > 1000 can leave signatures of Hydrogen recombination line emission which are redshifted into the Planck bandpasses at 143 and 353 GHz”

The scientific community believes that the results presented in the study by Ranga-Ram Chary are on the right track, but stress that it is necessary to study his findings in greater depth, to establish more solid conclusions and to be sure that what was identified isn’t something else… like space dust getting in the way.

(via)

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