Scientists recently made an important discovery: that DNA’s natural frequency can be altered by laser light. This modification is recorded within photon polarizations that make up the beam, producing a radio-wave spectrum which can be heard.
Understanding chromosomes as storage devices and transmitting systems for genetic information provides us with a new model of life: it is known as the wave genome.
Quantum nonlocality
Quantum nonlocality refers to an invisible connection between distant physical objects that cannot be explained using classical laws. It occurs as a result of quantum entanglement, where certain pairs of particles interact even though they may be separated by large distances. This theory has been applied in creating devices with increased computing capacities than regular electronics devices like computers such as quantum computers and in developing treatments against cancer and other diseases.
Misunderstandings about nonlocality often arise, leading to the mistaken belief that it implies the existence of some nonphysical realm or “spooky action at a distance.” But this is simply not true – nonlocality can be fully explained within quantum mechanics without additional assumptions or interpretations being required – its effects being stronger than predicted by standard Copenhagen interpretation of quantum physics!
One of the key findings related to quantum nonlocality is that it does not permit faster-than-light communication. Experimental evidence for this finding is provided by its impossibility; signals cannot travel faster than light between any points in space-time, due to various reasons; most importantly, such signal would require more entanglement than is currently available in nature.
Tsirelson’s bound and other results such as no-communication theorem serve to limit what entanglement can accomplish; however, thanks to recent technological developments scientists can now test and compare non-local quantum correlations, expanding their applications beyond secure communication and random number generation.
Scientists have recently found that DNA can be affected by electromagnetic, acoustic, and scalar waves; leading to the birth of the wave genome theory. According to this theory, each person possesses their own Wave Matrix which connects all their cells to one universal Zero Center; accessing this matrix requires special equipment called quantum resonance analyzers that reveal natural frequencies found in humans’ DNA which can then help determine whether it’s healthy.
Holographic memory
Holographic data storage involves the encoding of images using interference patterns created from optical interference between laser beams shining directly on an object to be stored and reflecting off it before reaching a plate, where their interference pattern encodes information about that object – even when physically broken up into fragments each fragment still can reconstruct the full object with reduced resolution.
A prototype holographic memory system stores one million pixels at once in discrete snapshots known as pages that form microscopic cones through the thickness of light-sensitive media. Its storage capacity is comparable to that of hard drives; however, retrieving it requires no physical contact between media and light source – providing access from any point at any time without losing information in the process. Furthermore, these holograms are rewriteable without losing any vital pieces of information.
The Holographic Model of Memory offers a revolutionary framework for understanding brain, trauma and consciousness. It proposes that memories are encoded as interference patterns spread across cognitive, emotional and bodily systems (cognitive, emotional and bodily). This model helps explain why traumatic memories often fragment into disconnected flashbacks or body sensations without narrative context; healing involves simultaneously targeting all these systems simultaneously and supports Antonio Damasio’s research on somatic markers as well as Jungian concepts of shadow in relationships.
To recover a holographic page of data, a second reference beam must be shone into the crystal at an equal angle to that used for recording it. When electrons that created the hologram recombine with holes from bright areas and leave the valence band, signal beams can detect changes in index of refraction that show changes to index refraction as changes to index of refraction rate; the slower this rate, the darker will be the intensity of the hologram.
When reading a page, a laser beam is shined onto a crystal at a different angle than its first reference beam, hoping that its new angle exactly echoes it and thus can be retrieved without error from holographic memory. Any deviation will result in an error message.
Semantic resonances
Semantic resonances refer to nonlocal transmission of information within our holographic universe and form an essential part of quantum wave theory of everything. DNA, the building block of genes, is thought to carry this nonlocal message across long distances due to its double helix structure which acts like a waveform in space; its pattern and repetition make it an excellent way of resonance; furthermore it has bioelectrical charges as well as vibrational modes which interact with electromagnetic fields – similar to quantum nonlocality! Scientists like Luc Montagnier have shown how water can retain information regarding DNA sequences similar to quantum nonlocality concepts!
Non-local signals can take the form of acoustic, electromagnetic or quantum waves that transmit information either encoded in DNA’s 98% non-coding material known as junk DNA that stores information as well as via fractals and geometric forms.
Studies reveal that DNA contains non-coding portions that resemble fractals and geometric forms. This suggests that chromosomes act like holographic memory banks that store and transmit information at extremely fast speeds, supporting theories that there may be connections between the microcosm and macrocosm – where information from one organism could transfer to others and alter their behaviors; potentially acting like an advanced form of telepathy while possibly also responsible for archetype transmission or culturally acquired traits.
Ulrike Granogger is a researcher and lecturer specializing in the intersection between spirituality and science. She writes regularly for Catherine Austin Fitts’ Solari Report about quantum biology and DNA’s holographic nature, thanks to her background as a linguist; furthermore, her passion for this subject led her to examine what she considers alternative or “future” science paradigms.
Biocomputer
A biocomputer is an innovative new type of computer which uses living organisms as its building blocks, following similar principles to silicon computers but using biological components like DNA molecules and protein-based circuits instead. A biocomputer provides several advantages over traditional computers, including faster data processing and parallelism as well as helping researchers quickly identify drug candidates at reduced costs; however using living organisms raises ethical considerations that may preclude its use for certain applications.
Biological computing utilizes DNA’s information-storage and transmission properties to perform calculations, making use of its memory storage properties to perform calculations and perform calculations. Biological computing can be used to identify drug targets as well as predict interactions between potential medicines and their target proteins. Furthermore, it helps scientists create more effective methods of detecting infectious diseases more rapidly – it is particularly effective at this task due to taking longer to discover and require extensive testing before being treated effectively.
Though biological computers are more accurate than their electronic counterparts, they still present several limitations. DNA molecules do not replicate with as much stability and may cause errors during replication, while biological computers cannot perform all types of calculations as electronic circuits do. Yet biological computers still hold great promise to revolutionize science and improve our lives.
Not only does DNA store genetic information, it also contains an intricate system for transmitting that data between cells – known as “eukaryotic translation.” This process facilitates protein synthesis in response to environmental conditions – an invaluable mechanism that sheds light on gene expression processes within individual cells.
Recent advances in biological computing are being revolutionized by the discovery of RNA molecules. These versatile chemicals can perform logic operations both in vivo and in vitro and act as powerful signaling molecules allowing cells to respond quickly and precisely to external signals such as light or chemical changes, making RNA an outstanding candidate for biological computing applications.
