State of the Art
The topic of WATER occupies scientists worldwide. My interest focuses particularly on research findings concerning water interfaces, as they support my hypothesis regarding human cybernetic information transfer.
Approaches to solving the "pilsner glass experiment" and other important findings in information transfer
During an experiment conducted in my practice on April 21, 2006 (in the presence of Christoph Drösser, then editor-in-chief of ZEITWissen, and a representative of vdiNachrichten), physicist Prof. Martin Lambeck explained the phenomenon after the experiment (quote: "There, it moved.") using the principle of "coupled oscillation." According to the current state of physics, this explanation cannot be correct, since the Kölsch glasses float in the water. A rigid coupling medium is lacking, and therefore, rotational movement cannot be explained.
The "Pils Glass Experiment" suggests that every living cell in water can emit gravitational waves with a biocybernetic control potential, which activates a controlled torque of the water molecules near the cell wall. The summation of these torques yields the shear forces responsible for forward thrust. This raises the question of whether the water molecule, as a dipole, is responsible for the biomechanical functions, and whether the asymmetric, physical quantum effect of neutron and electron scattering from both hydrogen atoms is responsible for information processing.
Ein Another approach to explaining the non-material control process is based on scientific experiments on quantum teleportation conducted by Anton Zeilinger.
Thomas Elsässer, a German experimental physicist, studies the ultrafast physics of condensed matter. Water, as the medium for the most important biological processes, is one of the foundations of life on Earth. Whether as a "solvent" for biomolecules or as a supplier of protons for charge transport, Elsässer discovered ultrafast structural changes in the dynamics of intermolecular hydrogen bonds in liquids and biomolecules in aqueous environments. His research results demonstrate for the first time the extremely short structural memory of pure water.
New findings from 2015 demonstrate that water molecules form a layer with entirely new properties at interfaces.
Water at Boundaries
At interfaces, water molecules form a layer with completely novel properties.
Stephan Gekle (Junior Professor Dr. Stephan Gekle, University of Bayreuth)
SOFT MATTER
Liquid water and ice are chemically identical, but have completely different physical properties. Far less well-known is the fact that water is not always the same even in its liquid state. This is due to the spatially extended structure of the network of hydrogen bonds. When this network is intersected by an interface, a new type of liquid water is created: interfacial water. Its properties differ in many respects, often fundamentally, from those of normal, liquid water ("bulk" water).
(4 Physics Journal 14 (2015) No. 11 © 2015 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim)
News from the Max Planck Institute for Polymer Research
The institute, with its six research groups led by six directors, is one of the world's leading research centers in the field of polymer science. Water is the basis for many biological, chemical, and physical processes. The interface of water in contact with other materials is ubiquitous and crucial for fields such as catalysis, biology, geochemistry, electrochemistry, and atmospheric chemistry. The microscopic structure (<1 nm) and dynamics of water, both in bulk water and at aqueous interfaces, are of paramount importance for understanding these processes. We investigate water by applying and developing cutting-edge spectroscopic methods to gain new insights into these relevant interfaces. In the field of "water," the working group is particularly interested in the following topics: interaction of water with interfaces (Backus, Domke, Gonella, Hunger, Parekh, Wang), modeling of vibrational spectra of water (Nagata), the role of water in charge transfer and molecular geometry (Backus, Domke, Gonella, Parekh), and hydration of biotechnologically relevant molecules (Grechko, Hunger, Parekh). Together with other MPI-P groups, the central research topics of "water at interfaces," "structure formation in non-equilibrium," and "multiscale challenges" are being investigated.
Why “Living Water” Is Highly Ordered and So Valuable for Health
Hexagonal Water Structure at a Glance Ursula Maria Lang Communication Scientist Advisory Board Member of the St. Leonhards Academy Health and Environmental Journalist Expert in Career Counseling Our body water, in all our cells and intercellular spaces, naturally possesses a high degree of order when we are healthy and is ideally arranged in a hexagonal structure. If we drink high-quality water that still retains its natural order, such as artesian spring water, the body can immediately use this water in all metabolic processes without first having to convert it into such a water structure. This is because “Water I” with chaotic cluster structures (as is the case with many tap waters, for example) must first be converted into cell-permeable water with a high degree of order – or so scientists assume. https://st-leonhards-akademie.de/wasser/hexagonale-wasserstruktur.html
Physicists Discover New Phases of Water
Water Molecules Assume Exotic States Under Confined Conditions
September 26, 2022, Nadja Podbregar
The water molecule has some unique characteristics that can give water unusual and quite exotic properties depending on the conditions. © sitox/ iStock
Neither solid nor liquid: Under confined conditions, water can assume novel states, as physicists have discovered. According to their findings, a single layer of water molecules can transition into a "hexatic" phase even at room temperature—it is neither solid nor liquid, and the H₂O molecules rotate in place. At slightly increased pressure, this water then becomes superionic, assuming a state previously postulated only for planetary nuclei, as physicists report in "Nature." https://www.scinexx.de/news/technik/physiker-entdecken-neue-phasen-des-wassers/
Prof. Dr. Gerald Pollack: The Discovery of Hexagonally Structured Water
At the University of Washington, a fourth state of water has been discovered that could explain not only chemical anomalies but also the effects of energized water.
The discovery of hexagonal water has revolutionized science. This new state of water, known as "EZ water," exhibits some astonishing properties that are transforming our understanding of water.
www.umh.at/pdf/Prof_Pollack_Energetisiertes_Wasser.pdf
Sensational Research Led by Prof. Dr. Dmitry Budker
The Symmetry Between Matter and Antimatter: The MAM Section
What is the enigmatic dark matter made of, of which there are likely about five times as much in the universe as of the normal, familiar matter?
And why are planets, stars, and galaxies made of matter, while antimatter has largely disappeared from space? These questions are among the fundamental problems of physics. With a wide range of activities, the MAM (Matter AntiMatter Asymmetry) section is experimentally investigating which approaches point the way to explaining these phenomena.
… Properties of Matter and Antimatter
Another question in physics: Why do we observe so much more matter than antimatter in the cosmos today? In fact, matter and antimatter should have annihilated each other shortly after the Big Bang – the universe would then consist entirely of pure radiation. To shed light on this question, HIM researchers are participating in an experiment called GBAR at CERN in Geneva. (The Mainz GBAR contribution can be found here.) With this experiment, they aim to determine whether antihydrogen falls in the Earth's gravitational field in the same way as ordinary hydrogen – an experiment possible only with neutral atoms and not with charged particles, such as atomic nuclei.
Furthermore, HIM researchers trap ions of matter and antimatter in traps to compare their properties using highly precise measurement techniques. They are also involved in planning new antimatter experiments at accelerators, particularly FAIR in Darmstadt, and are developing new experimental techniques and measuring instruments for this purpose. …
Details on the HIM website
https://www.hi-mainz.de/de/forschung/forschungsbereiche/mam
https://budker.uni-mainz.de/
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