* Astronomy

Title: What Drives Our Accelerating Universe?
Authors: Sidney Bludman (Universidad de Chile, Santiago)
(Version v3)

The homogeneous expansion history H(z) of our universe measures only kinematic variables, but cannot fix the underlying dynamics driving the recent acceleration: cosmographic measurements of the homogeneous universe, are consistent with either a static finely-tuned cosmological constant or a dynamic 'dark energy' mechanism, which may be material Dark Energy or modified gravity (Dark Gravity). Resolving the composition and foreground noise to reduce their large systematic errors.dynamics of either kind of 'dark energy', will require complementing the homogeneous expansion observations with observations of the growth of cosmological fluctuations. Because the 'dark energy' evolution is at least quasi-static, any dynamical effects on the fluctuation growth function g(z) will be minimal. They will be best studied in the weak lensing convergence of light from galaxies at 0<z<5, from neutral hydrogen at 6<z<20, and ultimately from the CMB last scattering surface at z=1089. Galaxy clustering also measures g(z), but requires large corrections for baryonic composition and foreground noise. Projected observations potentially distinguish static from dynamic 'dark energy', but distinguishing dynamic Dark Energy from Dark Gravity will require a weak lensing shear survey more ambitious than any now projected. Low-curvature modifications of Einstein gravity are also, in principle, observable in the solar system or in isolated galaxy clusters. The cosmological constant can only be fine-tuned, at present. The Cosmological Coincidence Problem, that we live when the ordinary matter density approximates the 'gravitational vacuum energy', on the other hand, is a material problem, calling for an understanding of the observers' role in cosmology.

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In the early Universe, small fluctuations in energy density and pressure caused oscillations. Although tiny in the beginning, these ripples have been magnified by the expansion of the Universe so that they stretch 500 million light-years across today.
The clouds of neutral hydrogen should follow the same ripple pattern, so astronomers will know they're looking at those first, primordial clouds, and not some closer ones.
And so, astronomers will be able to look back in time, and study the distance to the clouds at each epoch in our Universe's expansion. They should be able to trace how much dark energy was affecting space at each time, and get a sense if this energy has always remained constant, or if it's changing.

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Ed ~ ignore the  `Big Bang doubtful` part, as  that will only be of concern to beings 300 billion years from now.

Title: The Destiny of Universes After the Big Trip
Authors: A.V. Yurov

The big trip can be describe with the help of the Wheeler-DeWitt wave equation {\hat H}\psi(w,a)=0. The probability to find the universe after big trip in the state with w=w_0 will be maximal if \partial\psi(w,a)/\partial w|_{w=w_0}=0 for any values of the scale factor a. It is shown that this will be the case if and only if w_0=-1/3. This fact allows one to suggest that vast majority of universes in multiverse must be in this state after their big trips.

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'Seesaw' explains light dark-energy particles
Eight fields would interact to produce a single particle

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