Irene Caesar recently demonstrated how DNA can be moved non-materially across long distances using laser modulation – this pioneering work hailing from Russia’s forefront of quantum DNA research.
WAVE GENOME LLC has tailored their electret-based generators with each client’s individual Wave Matrix for reading by their PSI generator, providing for unique nonlocal communication between WAVE GENOME generators and Bioholograms of clients.
Electret Excitation
Electrets are dielectric materials which store polarization charges and generate both internal and external electric fields, acting like magnets but electrostatically instead. Since Michael Faraday conducted experimental researches into electricity, electrets have existed as electrostatic equivalents of magnets. Oliver Heaviside first coined the term “electret” in 1885.
An electret’s properties are determined by its charge density (surface potential Vs, volumetric charge density s) and storage lifetime, the latter depending on factors like composition of dielectric material used and charging process. An important feature of an electret is its stability under light irradiation as well as at elevated temperatures.
Electret films may be charged through various methods, including thermal charging, radiation charging and corona charging. Two primary schemes for charging thin PTFE films are tribocharging (where large areas of film are charged through contact with thin liquids such as water or ethanol) and corona charging – each producing electrical charges when different objects come in contact. Tribocharging is one of several forms of triboelectricity; when dissimilar objects come into contact with each other they generate voltage between themselves.
One approach for charging an electret involves applying a DC voltage between its electrodes, creating an electric field which can alter the direction of charge within its film. Once reversed, charge will no longer repel polarizers in one direction and produce an internal electric field that can then be used to excite polarizers in samples. The resultant electrostatic field can then be used to excite the polarizers. This method can also be used to excite a thin layer of polymer that contains polarizers, often found in the manufacture of spectroscopic equipment. Furthermore, this technique is effective at determining concentration of polarizers in samples as well as wavelength of radiation being measured; and can even harvest vibration energy! Furthermore, its applications range from air particle analysis and measuring radiation or radon exposure levels through to harvesting vibration energy harvesting applications.
Quantum Biononlocality
Scientists have recently discovered evidence that quantum phenomena such as entanglement, photons, and coherence play key roles in cell communication and homeostasis. This new understanding of biological nonlocality may shed light on why living systems react to their environments in ways classical mechanics cannot.
Experiments providing direct evidence of quantum nonlocality of chromosomes include those which directly link laser radiations produced by the genome apparatus to laser radiations produced by laser diodes that produce laser light that converts directly into coherent continuums of radiowave genomic information. Furthermore, experiments demonstrate how biosignals generated can be stored in a fractal liquid crystal phase of the genome apparatus that acts as memory that can then be accessed computational processes that generate new genetic information or control gene expression as needed.
These results are based on the assumption that biomacromolecules such as DNA, RNA and proteins contain information which has the capacity to polarization-modulate light and radio waves using optical rotatory dispersion and circular dichroism; similar information transmission occurs through optical fiber lasers.
Note that quantum experiments, like all those involving classical mechanics, violate the principle of locality; classical mechanics states that systems can only be affected by their immediate surroundings and any influence emitted from one part to another must not exceed the speed of light. But quantum mechanics provides an exception to this rule by linking properties of entangled particles whose values appear to be inextricably linked – measuring any property of one of these entangled particles can instantly set its value despite being separated by large distances.
These effects are typically described as violating the Copenhagen interpretation of quantum theory; however, some researchers have proposed an alternate explanation involving “macroscopic locality”. This interpretation allows microscopic experiments to breach Tsirelson’s bound without violating Bell’s nonlocality limit – providing an explanation for seemingly contradictory experimental data results.
Quantum Biocomputer
Studies of electromagnetic waves’ interaction with DNA have opened a new field of science. Electromagnetic waves can alter its genetic code, enabling its reading or rewriting – this phenomenon is known as Wave Genome. Scientists have also discovered that it can be altered by other waves like acoustic, holographic and scalar waves; opening up many possibilities for future applications.
These discoveries are opening the way to quantum biocomputers, which use quantum nonlocality to store and process large amounts of data more quickly than conventional computers, as well as solve difficult problems not easily addressed with current algorithms.
Essentially, biological systems can be understood as being one single quantum system, meaning that anything that happens in one part will have an effect on another part. DNA of living cells and substances has the capacity to act as a resonant quantum system which allows it to receive information from all areas of our bodies.
In these experiments, the quantum biocomputer consists of a Helium-Neon laser that emits coherent optical visible radiation. This emission consists of two orthogonally coupled optical modes whose intensities can be modulated biologically active polarization dynamics of donor objects with which it interacts.
As the radiation from these objects emanates into the environment, a special detector can detect it. The Fourier spectrum recorded by this detector reflects their polarization-dynamic properties of donor objects – this biosign can then be used to assess their status or search for biologically active molecules.
As such, the genome-biocomputer can “read and comprehend” text-like biological texts similar to human thinking. These texts then shape and form evolutionary texts of multicellular organisms, leading to profound shifts in our understanding of genetic code and evolution. Furthermore, multicellular organisms possess something resembling static-dynamic multiplex holographic grid chromosome apparatus with nucleotide sequences similar to texts that the gene-biocomputer can understand at its own genomic “reasoning level”. Thus transmitting genome data higher in an organism such as brain level.
Quantum Leap
Quantum genomics advances are giving rise to an entirely new field of science – quantum biology. This field explores applications of quantum mechanics within biological systems. Already it has allowed us to observe DNAs evolving within living cells as well as genetic mutations occurring over time.
These advances will enable researchers to better understand how genetic information is stored and transmitted within cells, while also offering insight into cancer, autism and other diseases’ triggers. Soon enough, perhaps we will even be able to use this technology to manipulate genomes on a molecular level.
DNA is a quantum particle that emits waves, making it possible to transport, or teleport it, immaterially and nonlocally. This has immense implications for medical and technological breakthroughs – imaging a world where DNA could be transferred with lasers, programmed with waveforms or even beamed across space! Russia has made notable strides in quantum DNA research such as Peter Gariaev’s experiments in wave-genetics research that could realize such vision.
BGI-Research researchers recently published a paper detailing how they utilized quantum computing to solve the de novo genome assembly issue. By converting haplotype assembly into an optimization problem that could be solved with quantum annealer technology, high precision results for diploid and polyploid genome assemblies were achieved and published in Cell Reports Methods on April 20,24.
The authors of the paper suggest that their approach will provide a more precise and complete portrait of genome evolution. Scientists can use it to study how genetic code has evolved with time due to environmental influences; and use this understanding of disease development over time as well as how human genome has progressed over time.
Quantum leaps are scientific revolutions with the potential to alter how we live and work. By expanding our understanding of physical reality, they enable us to produce materials with extraordinary strength and precision – opening up endless opportunities in personal and professional lives alike. They alter how we relate to reality as well as ourselves – helping us realize true potential, fulfill dreams that fill our hearts, bring peace and happiness for everyone on earth – but most of all they bring peace and happiness for humanity itself.
