(image AI generated)
Energy, more than any other force, shapes the cosmos. Consider the following: the observable universe is 93 billion light-years in diameter. Yet, if you were to gather all of the baryonic matter within it—every star, planet, and cloud of gas—and condense it into a single cube with the density of water, each side of that cube would measure just 5.5 light-years.
To put that scale into perspective, imagine printing a high-resolution photograph of the Pinwheel Galaxy to fill an entire A0 sheet of paper. If you were to take a needle and make a tiny pinprick anywhere on that image, all the physical matter in the cosmos, at the density of water, would easily fit inside that single pinprick.
Space is not defined by the solid things within it, but by the energetic framework that separates them. What we perceive as a vast, empty void is, in reality, a dynamic, highly tensioned proper time field driven by the Planck power flux and characterised by its 3D isotropic metric stiffness aF = cH(z)/12Pi. We explore these ideas in “The Emergent Time Framework: Resolving the Dark Sector and Hubble Tension Through Planck Power” DOI 10.17605/OSF.IO/RCWJ3
(image below of Pinwheel Galaxy courtesy NASA)
