III. Ecosmos: A Revolutionary Fertile, Habitable, Solar-Bioplanet Lifescape
1. Quantum Cosmology Theoretic Unity
Gates, Evalyn. Einstein’s Telescope: The Hunt for Dark Matter and Dark Energy in the Universe. New York: Norton, 2009. Among a spate of popular books about an accelerating cosmic science, this is a well-written volume by the assistant director of the Kavli Institute for Cosmological Physics at the University of Chicago. It is inspired by Albert’s 1936 conjecture that the way gravity bends space could be availed as a vast lens to delve celestial frontiers. For an apropos quote, we offer an Overview from the Kavli website.
Cosmological discoveries over the past two decades …. have found that the Universe is a giant particle accelerator which enables particles to have energies that are 30 million times higher than those found in terrestrial accelerators. Another area where physics and astronomy are intertwined is in understanding "dark matter". The Universe contains large amounts of "dark matter" which scientists feel is made of a particle that is yet to be discovered. The origin of structure in the Universe such as galaxies and clusters of galaxies is believed to have happened through sub-atomic quantum fluctuations, whose ripples we see as tiny fluctuations in the temperature of cosmic microwave background across the sky. These and other discoveries show that physics at the smallest scale - interactions of the quarks and leptons - is intimately connected with the largest scale - the constitution and birth of the cosmos itself.
Gates, James. Symbols of Power. Physics World. June, 2010. A renowned African-American physicist at the University of Maryland proposes that traditional geometric symbols known as “adinkras” might again serve to help illuminate nature’s creative informational qualities.
Could it be that codes, in some deep and fundamental way, control the structure of our reality? In asking this question, we may be ending our “treasure hunt” in a place that was anticipated previously by at least one pioneering physicist: John Archibald Wheeler. (39) As for my own collaboration on adknkras, the path my colleagues and I have trod since the early 2000s has led me to conclude that codes play a previously unsuspected role in equations that possess the property of supersymmetry. This unsuspected connection suggests that these codes may be ubiquitous in nature, and could even be embedded in the essence of reality. (39)
Gebrehiwot, Yikdem, et al. On Utmost Multiplicity of Hierarchical Stellar Systems. arXiv:1701.01135. We cite for its content, and for the current reach of intercontinental collaborations. The lead author is at the Entoto Observatory, Ethiopia, followed by seven Russian astronomers with other postings in South Africa. The paper is to appear in the journal Baltic Astronomy from Vilnius, Lithuania.
According to theoretical considerations, multiplicity of hierarchical stellar systems can reach, depending on masses and orbital parameters, several hundred, while observational data confirm existence of at most septuple (seven-component) systems. In this study, we cross-match very high multiplicity (six and more components) stellar systems in modern catalogues of visual double and multiple stars, to find candidates to hierarchical systems among them. After cross-matching with catalogues of closer binaries (eclipsing, spectroscopic, etc.), some of their components were found to be binary/multiple themselves, which increases the system's degree of multiplicity. Optical pairs, known from literature or filtered by the authors, are flagged and excluded from the statistics. We have compiled a list of potentially very high multiplicity hierarchical systems that contains 10~objects. Their multiplicity does not exceed 12, and we discuss a number of ways to explain the lack of extremely high multiplicity systems.
Gibbons, G. W., et al, eds. The Future of Theoretical Physics. Cambridge: Cambridge University Press, 2003. A stellar constellation of articles in honor of Stephen Hawking’s 60th birthday. Many leading cosmologists such as Martin Rees, Alan Guth and Andrei Linde contribute their latest imaginings on the dynamic nature, shape and fate of space-time and our human ability to comprehend such vistas.
Gielen, Steffen and Joao Magueijo.
Quantum Resolution of the Cosmological Singularity.
We cite this posting by University of Sheffield and Imperial College London physicists as one example of frontier Earthuman abilities to plumb and span, so it seems, any depth and breadth of the entire universal expanse, and beyond. Once again it is fantastic to contemplate that such “microcosmic” entities themselves, as they now altogether reside and collaborate within a global cerebral-sphere, can yet accomplish these quantifications across so many orders of magnitude. Might a reason be that planetary peoples are ultimately meant to become ecosmic cocreators?
Giudice, Gian. A Zeptospace Odyssey. Oxford: Oxford University Press, 2009. A CERN physicist evokes the Large Hadron Collider as the ultimate microscope now able to peer into this “zeptometre” zone of a billionth of a billionth of a millimeter. Its supposed mission is to find some missing, crucial clue in a material haystack that would connect to and explain the multiverse. Or maybe the last hurrah of a left brain male hunt as it disappears into this black hole of a machine, oblivious to a radically developmental universe to human genesis. Or as Brian Josephson tries to say due to creative, self-organizing forces that will not be found in the LHC.
Gnedin, Nickolay. Digitizing the Universe. Nature. 435/572, 2005. A report on a detailed article in the same issue (Springel, Volker, et al. Simulations of the Formation, Evolution and Clustering of Galaxies and Quasars.) on the work of an international collaboration known as the Virgo Consortium. This group uses novel, sophisticated computational astrophysics including simulations of dark matter (invisible material that is the main source of gravity) to achieve the most realistic model to date of our dynamically evolving cosmos.
Greene, Brian. The Elegant Universe. New York: Norton, 1999. An elegant exposition of frontier physics and especially multi-dimensional string theory as it strives to unify the quantum and relativity domains.
Greene, Brian. The Fabric of the Cosmos. New York: Knopf, 2004. In a sequel to his 1999 bestseller The Elegant Universe, the Columbia University physicist and impresario provides another accessible entry to the celestial, temporal and quantum realms of a multidimensional reality. Of especial interest is an explanation of the Holographic Universe theory, whereby our extant 3D world may be a projection from information on a 2D surface. The hologram scenario is most apropos because each minute section contains a refraction of the whole image.
Greene, Brian. The Hidden Reality: Parallel Universes and the Deep Laws of the Cosmos. New York: Knopf, 2011. The Columbia University physicist surely does communicate such far outer reaches and dimensions of theoretical imaginations with verve and veracity. Quilted, Inflationary, Brane, Cyclic, Landscape, Quantum, Holographic, Simulated, and Ultimate Multiverse options are clearly explained, amidst their wonderment. But, but, as per the quote, in this so declared final Copernican displacement, as if physics disappearing into its own, self-made black hole, all human hopes, sensibilities and reprieves of a meaningful destiny are to be abandoned.
Rather, what’s gratifying about being human, what’s exciting about being part of the scientific enterprise, is our ability to use analytical thought to bridge vast distances, journeying to outer and inner space, if some of the ideas we’ll encounter in this book prove correct, perhaps even beyond our universe. For me, it is the depth of our understanding, acquired from our lonely vantage point in the inky black stillness of a cold and forbidding cosmos, that reverberates across the expanse of reality and marks our arrival. (8)
Guth, Alan. The Inflationary Universe. Reading, MA: Addison-Wesley, 1997. A sudden expansion of the cosmic singularity in its first seconds is proposed by the MIT cosmologist to resolve mathematical and observational disagreements, which has now become the generally accepted model.
Guth, Alan and David Kaiser. Inflationary Cosmology: Exploring the Universe from the Smallest to the Largest Scales. Science. 307/884, 2005. A thorough survey of the latest theories and observations in this regard prepared for the International Year of Physics.