Ulrike Granogger is an intrepid researcher and lecturer passionate about exploring how science intersects with spirituality. A contributor to Catherine Austin Fitts’ Solari Report, Ulrike Granogger champions “future science”.
Scientists were recently able to detect the electromagnetic signature of DNA in a vacuum for the first time ever – marking an impressive step toward DNA holography.
Quantum holography of DNA
The DNA molecule can be seen as a quantum hologram – more than simply an array of nucleotides and codons – which contains information encoding both genetic information about an organism as well as all past and future events. The dynamical system that encodes this hologram operates via phase conjugate adaptive resonance; acting like an operating computer using DNA-wave biocomputation principles with quantum teleportation capabilities.
According to this theory, DNA transmits the genetic code of individuals and bio-systems via photon waves encoded at polarization level – nonlocal wave codes which comply with Einstein-Podolsky-Rosen effect; DNA can thus carry nonlocal information regarding any bio-system to any location on earth.
A DNA-based biocomputer comprises of a self-calibrating antenna which works via phase conjugate adaptive resonance, receiving and transmitting quantum holographic information stored within its diffraction patterns. This allows DNA to transmit both its own genetic code as well as that of an organism from any point in space and time to any other point.
DNA solitary waves (also called quadrupolar solitons) serve as a dynamical memory device, helping preserve and transmit initial modes of energisation in nonlinear systems. Solitary waves are generated within liquid crystal DNA chromosomes via resonance coupling with external electromagnetic fields such as radio or light frequencies, creating these dynamical memory devices.
These waves can be considered the language of life, as they contain all of the information needed to form all forms of matter and energy at both macro and micro levels. This information is transmitted through DNA’s unique fractal patterns of vibrational wave interactions that convey this vital message.
DNA’s fractal nature can be explained by its holographic properties, which allow its living genome to project bio-holograms on both cell and whole organismic levels, creating complex patterns of standing and moving electromagnetic wavefronts encasing it and surrounding biosystems with electromagnetic standing waves and moving wave fronts. Furthermore, this phenomenon of quantum nonlocality also arises as part of DNA.
The fractal nature of the genome
Researchers have made an important discovery: that DNA’s chromatin structure is fractal. This revelation marks an essential step in understanding genome dynamics. Chromatin serves as nuclear scaffolding which holds DNA component securely while also providing pathways for interaction with proteins involved in various biological transactions through diffusive processes or target search mechanisms; predictability is achieved thanks to fractal architecture of chromatin architecture.
Human chromosomes and four other genomes were measured using the box counting method for measuring their fractal dimensions, with results showing power-law scaling behavior over five orders of magnitude in scale. Furthermore, as compactness increased so did gene density levels demonstrating how fractal models provide an invaluable way of interpreting large-scale genomic patterns.
Fractal theory has long been used to understand complex physical systems like earthquakes, clouds and plants; its applications to chromatin research remain less widely known due to fractal structures being self-similar over narrow spatial lengths instead of across wider domains. Therefore it is necessary to develop new paradigms to comprehend functional consequences associated with fractal chromatin structures.
Multifractal approaches offer researchers an ideal means of discovering correlations among various aspects of the genome. Its application can help pinpoint regions important to cell function and stability as well as explain why some genes respond more actively than others to environmental signals.
Researchers set out to explore whether fractals were essential for cell function by conducting an experiment called RM, where human chromosomes were evaluated for multifractality using the computational method RM. Their results revealed that multifractality of human chromosomes was affected by Alu and CGI content as well as long interspersed repeat dimensions, correlating with multifractality of long interspersed repeats fractal dimensions; all suggesting fractal models of genome may play an essential role in both genome stability and evolution.
The holographic nature of life
The Holographic Principle is an essential principle in physics and has been utilized to interpret quantum gravity and string theory. This principle suggests that matter and energy exist in constant balance, that our universe contains an encoded picture of each particle’s interactions, as well as that physics laws are nonlocal holograms.
Scientists have recently studied a phenomenon called the “information entropy of matter.” This measure determines how much information is necessary to accurately describe physical properties in any system and, according to research conducted, can also serve as a holographic measurement of energy distribution within said system – this significant finding proves that our universe is not an impenetrable cocoon and shows how energy and information can spread freely across vast distances.
Physics experts believe the universe is an enormous hologram with vast amounts of information stored about all its constituents, which are subdivided infinitely and have similar entropies as their parent particles, leading to infinite subdivision. If this were possible, an infinite subdivision of any particle would violate the maximum entropy density limit in existence and lead to chaos and inefficiency in nature.
Scientists are exploring the possibility that living organisms may also exhibit holographic properties. One such organism is DNA, which has been observed exhibiting its holographic qualities during experiments demonstrating living cells emitting light. Such studies suggest that DNA acts not only as an information storage device for its genetic code but also acts as an electromagnetic carrier to transmit cell messages.
Researchers conducted an experiment wherein they placed a piece of DNA into a chamber and measured its electromagnetic signature before extracting and reading out what is known as phantom readout, the result of which later published in Science magazine.
Peter Gariaev conducted another experiment that demonstrated DNA can be holographically transmitted using biophotons emitted by living cells, suggesting it exists as electromagnetic entities that could lead to new medical and technological breakthroughs. Further investigation in this field may provide solutions for more health care needs or technological advancement.
The holographic nature of intelligence
As our world increasingly digitizes, it’s essential that we remember intelligence is nonlocal. Our minds possess an incredible ability to tap into universal resources through brainwaves and other sensory responses – this connection serves as the cornerstone of consciousness and reality itself; the more we comprehend its workings, the sooner we will realize our full potential and become better versions of ourselves.
Researchers have used the holographic principle to demonstrate how DNA can encode information about itself in two dimensions, which can then be read with a laser beam scanner. The laser produces interference patterns similar to diffraction patterns of holograms. This process allows researchers to assess chemical and vibrational aspects of samples.
Physical Review Letters published the results of this experiment as a first step toward understanding the holographic nature of our universe. According to researchers, an algorithm used in this research works by iteratively removing detail features of physical systems until reaching a more stable structure level; this allows the algorithm to generate quantum field configurations on holographic boundaries and propose bulk gravity theories.
This discovery may help scientists better comprehend the duality between matter and energy in our universe. While electromagnetic, weak, and strong forces can all be described using quantum mechanics, gravity remains unexplored by any established theory. Holographic gravity might provide an explanation for this phenomena – it might help reveal one of its major mysteries!
Though this is an exciting development, many do not fully grasp its implications. Physicists have been exploring this theory for three decades without yet fully elaborating it. Recent findings are the result of collaboration among researchers from around the world led by Uziel Awret from Alexandria’s Inspire Institute whose holographic principle may also explain our brain’s communication abilities.
