As pointed out by physicist Professor Bernard Carr of the University of London in his June 2008 published paper, Sarfatti has been working on the Wheeler-Feynman advanced potential electrodynamical interpretation of the dark energy Einstein cosmological constant accelerating the expansion speed of space. Hoyle and Narlikar showed that the zero point virtual photons thought to be the dominant component of dark energy are from the advanced electromagnetic potentials emitted by the perfect future absorber in a consistent loop in time called a "transaction" by Professor John Cramer of the University of Washington. Sarfatti and Levit suggest that our observer-dependent future cosmological de Sitter horizon is a Wheeler-Feynman perfect absorber. The virtual photon dark energy density we measure from the anomalous redshifts of Type 1a supernovae in our past light cone are complementary to advanced Hawking blackbody Unruh radiation of real photons from the surface gravity of our future horizon of 10^123 Bekenstein BITs that obeys the t'Hooft-Susskind holographic principle. All objects in our 3D material observable universe piece of the multiverse are retro-causal 3D hologram images of 2D patterns on our future cosmological de Sitter horizon that we are inside of is the idea Sarfatti is proposing in his 2009 paper with Levit. This is consistent with S-Matrix unitarity that information is not fundamentally lost. Sarfatti connected the nonlocally smeared 2D information on our future horizon hologram screen to David Bohm's "implicate order" with all 3D material objects as the hologram images in Bohm's "explicate order." Sarfatti and Leonard Susskind were graduate students together at Cornell and worked with Jonathan Glogower on the problem of time in quantum theory. Susskind in his book "Cosmic Landscape" says that the problem of why the dark energy density is so small is a major challenge in physics today. Sarfatti suggests that Susskind's own holographic conjecture is the answer once the role of Wheeler-Feynman advanced influences from our future horizon is recognized. Sean Carroll's arrow of time problem ("From Eternity to Here"), i.e., why we age as the universe gets bigger, is also automatically solved because the entropy of our observable universe is the area of our future horizon that is 1 BIT at the moment of inflation saturating at the asymptotically constant de Sitter value of ~ 10^123 BITs because of the finite speed of light in the accelerating universe. Sarfatti's ideas on these problems are still largely unknown to the mainstream physics community. -- from Wikipedia