BIRD FEATHERS AS ELECTROMAGNETIC ENERGY TECHNOLOGIES
- magixman7
- 8 hours ago
- 14 min read
The idea that bird feathers, including peacock feathers, could function as sophisticated antennas to perceive the entire electromagnetic spectrum is a fascinating indeed and here are some key points to consider :
Feather Structure: Bird feathers are primarily made of keratin and consist of a complex arrangement of barbs and barbules.
They can reflect and refract light in interesting ways, with their main functions related to insulation, waterproofing, as well as display electromagnetic sensing.
Vision in Birds: Birds have highly developed vision and can see ultraviolet (UV) light, which is beyond the visible spectrum for humans.
This ability is due to specialized photoreceptor cells in their retinas.
The presence of UV-reflective patterns in feathers play a role in communication and mating displays.
Electromagnetic Spectrum:
The electromagnetic spectrum includes a wide range of wavelengths, from radio waves to gamma rays.
While some animals have evolved to perceive specific parts of this spectrum (e.g., infrared sensing in some snakes)
....... birds rely mainly on visible and UV light for their visual capabilities.
Research on Feathers:
Some studies have looked at the reflective properties of feathers and how they enhance visual signals and camouflage.
The striking colours of the peacock’s feathers, that appear to change as the feathers move, are due only in part to “ordinary colour”.
The feathers possess a nanostructure – a repeated structure so small and precise that, while it is invisible to the naked eye, it interacts with light waves to change the way we observe them.
This is called “structural colour” and is what is responsible for the iridescent quality of a peacock’s feathers.
The nanostructure of the feathers means that when light hits them it is reflected off them at different points, so a number of different light waves is reflected back.
The reflected light waves interact with each other and result in interference.
This means that if the waves are in phase, in other words if they have their peaks and troughs at the same points, they will be amplified;
....... if they are not in phase they will be partly or entirely cancelled out.
Because light waves with different wavelengths appear as different colours, some colours are amplified and some are cancelled out;
....... depending on the feather’s structure.
As you, the observer, move, the colours appear to change as different wavelengths are amplified in the direction of the viewer.
Peacocks are not alone in nature in possessing structural colour.
The striking beauty of the butterfly’s wing, the delicate iridescence of mother-of-pearl and the magnificent shells of some beetles are other examples.
Scientists have learnt a great deal from studying these natural examples of structural colour and many attempts have been made, with some success, to recreate these colours artificially.
“Birds can make only about 26 to 30 percent of the colors they are capable of seeing but they have been working hard over millions of years to overcome these limitations.”
So, it appears we are colorblind compared to birds that can see many more spectrums colors than we as humans can.
So since birds only produce in their feathers up to 30% of colors they can see in total, then no, those birds cannot see more colors than what their colored feathers reflect.
However, that doesn’t mean they cannot see things that contain colors that don’t exist in their feathers. Like mentioned above, birds see far more colors than us.
Are a Birds Feathers Sophisticated Antenna
It seems there is static electric charge stored in the feathers of birds. The static charge helps in repelling water from the feathers.
When observing chickens being beheaded they can sometimes walk around headless and still be perfectly balanced.
Static electric charge of the feathers and the sensory array for the feathers keep the bird balanced.
The birds feet provide "grounding" insulation from the ground and it is that the tip of the beak emits charges from the electrostatic complex.
Thus allowing signaling to another birds by “rays” straight from the tip of the beak.
It's also understood that feathers also provide sensing of electromagnetic waves.
The tail and two wings are independent sensing, allowing for a sense of depth in the incoming electromagnetic radiation.
The infrared radiation and heartbeat of mammalian pray is observed in this way by predator birds such as an eagle or falcon.
There is no limit what wavelength can be sensed when proper arrangement of feathers allows for sensing frequencies in this way.
Radiation related from particles entering the atmosphere being attracted by earth´s magnetic field is absorbed by the birds feathers and sensed in some way, such as “vision”. This explains how birds navigate across the whole planet.
Electromagnetic radiation from human sources, electric equipment etc. is also used by birds in navigating to a specific place.
PVS: [The Avian Marvel: Birds' Feathers as Sophisticated Antennas
In the realm of biomimicry, where nature's ingenuity inspires human innovation, the humble feather stands as a testament to evolution's brilliance.
Beyond its role in flight and insulation, the feather conceals a secret: it's a sophisticated antenna, attuned to the subtleties of its electromagnetic spectrum surroundings.
Tuning In: The frequency Structure of Feathers
Like the delicate filaments of a radio antenna, feathers are composed of intricate structures that interact with their environment.
The vanes, barbs, and barbules that make up a feather's architecture create a complex system that responds to various stimuli.
This intricate design allows birds to harness and interpret a wide range of signals, from the gentle rustle of leaves to the whispers of potential prey, from the shumann frequencies to the rf-signal cell towers.
Receiving and Transmitting: The Electromagnetic Spectrum
Feathers, much like antennas, can detect and respond to electromagnetic signals.
Research has revealed that birds use their feathers to detect the Earth's magnetic field, which aids in navigation during migration.
This remarkable ability is akin to a GPS system, guiding birds across vast distances with accurate precision.
Adaptation and Evolution: The Antenna's Refinement
Just as human technocrat engineer refines cell tower antenna designed to optimize biometric internal surveillance signal reception;
.......evolution has honed the feather's structure to serve the bird's needs.
The shape, size, and arrangement of feathers on a bird's body are tailored to detect specific signals;
....... whether it's the vibrations of a predator's footsteps or the changes in air pressure that signal an approaching storm;
.......avians are indeed equipped with miriad of feathers that operate collectively as a multidimensional force of one, denoting the birds mystical spirit totem powers.
The Avian Advantage: A Symphony of Senses
Birds' feathers, functioning as sophisticated antennas, contribute to a multisensory experience that enhances their perceptions, survival and their success.
By integrating visual, auditory, tactile, and electromagnetic cues, birds navigate their environment with remarkable agility and precision.
This Avian synergy of senses is like a masterfully crafted mosaic, where each piece, though distinct, comes together to form a vibrant and cohesive image, revealing a beauty and complexity that transcends its individual components.
The feather's role as a sophisticated antenna underscores the ingenuity of nature's designs.
As we continue to explore the intricacies of avian biomimicry, we may uncover even more remarkable examples of how the natural world inspires innovation and pushes the boundaries of human understanding.
Electromagnetic pollution such as cell towers that emit rf-signals, ruin the navigational skills of birds.
The Silent Scream of the Skies: How Electromagnetic Pollution Disrupts Avian Navigation
In the ethereal dance of bird migration, where celestial cues and magnetic fields guide flocks across continents, a silent disruptor has emerged:
Electromagnetic pollution from cell towers and the HAARP.
Cell towers, especially the HAARP, emitting radio frequency signals (RF), have become an ominous and omnipresent force, altering the navigational landscape for birds.
The consequences are dire, as these avian navigators struggle to chart their courses amidst the electromagnetic cacophony.
Disrupting the Compass: RF Signals and Magnetoreception
Birds rely on magnetoreception, a biological compass that detects the Earth's magnetic field, to navigate during migration.
This innate ability is thought to be mediated by specialized cells containing magnetite or cryptochrome proteins, which respond to magnetic cues.
NOTE:
Unveiling the Biological Compass: Specialized Cells and Magnetic Cues
The intricate dance of magnetoreception in birds relies on specialized cells containing magnetite or cryptochrome proteins.
These cells are the biological basis for detecting the Earth's magnetic field, enabling birds to navigate during migration.
Magnetite: A Magnetic Mineral
Magnetite is a naturally magnetized iron oxide mineral found in biological systems.
In the context of magnetoreception, cells containing magnetite act like tiny compass needles, rotating and aligning themselves with the Earth's magnetic field.
This alignment triggers signals that are interpreted by the bird's brain, providing information about direction and location.
Cryptochrome Proteins: Light-Dependent Magnetoreception
Cryptochrome proteins are sensitive to blue light and are thought to play a role in magnetoreception.
These proteins form radical pairs, which are influenced by the Earth's magnetic field.
The magnetic field affects the spin state of these radical pairs, leading to changes in the signaling pathways within the cell.
This process is akin to a light-sensitive switch, where the magnetic field modulates the response to light.
Responding to Magnetic Cues: A Cellular Mechanism
The response to magnetic cues involves complex cellular mechanisms.
When magnetite or cryptochrome proteins interact with the Earth's magnetic field, they trigger a cascade of signals that ultimately inform the bird's brain about its orientation and location. This process can be likened to:
- A compass needle aligning with magnetic north: The specialized cells respond to the magnetic field, providing directional information.
- A sensor detecting changes in light intensity: Cryptochrome proteins respond to the magnetic field's influence on light-dependent reactions, allowing the bird to detect magnetic cues.
- A GPS system providing location information: The integration of magnetic cues with other sensory information enables the bird to determine its location and navigate during migration.
Specialized cells containing magnetite or cryptochrome proteins respond to magnetic cues by triggering signals that inform the bird's brain about its orientation and location.
This intricate biological mechanism enables birds to navigate during migration, leveraging the Earth's magnetic field as a reliable guide.
RF signals from cell towers, interfere with this delicate system, effectively "jamming" the birds' magnetic compass.
Imagine a GPS system, once precise and reliable, now clouded by static and noise, rendering it useless.
The 2007 Avian Catastrophe: A Harbinger of Electromagnetic Disruption
On New Year's Eve, 2007, a mysterious event unfolded in Beebe, Arkansas, where thousands of red-winged blackbirds suddenly dropped dead in flight, and fell from the skies [HAARP].
The exact cause was an electromagnetic pulse wave disruption [similiar to the sept. 11th attack that dropped the WTC towers] most definitely has played a role.
The electromagnetic pulse wave disruption on sept. 11th that dropped the WTC towers came from a Particle Collider located at Brookhaven National Laboratory in Upton New York.
This particle collider located at Brookhaven National Laboratory in Upton, New York, called the Relativistic Heavy Ion Collider, or RHIC similar to The Large Hadron Collider, the world's largest and highest-energy particle accelerator, situated in a tunnel about 175 meters beneath the France-Switzerland border near Geneva.
It's operated by the European Organization for Nuclear Research, CERN.
The Particle Collider located at Brookhaven National Laboratory in Upton, New York, called the Relativistic Heavy Ion Collider, or RHIC. It's used by researchers to study the universe's earliest moments by colliding ions at relativistic speeds, creating temperatures over 4 trillion degrees Fahrenheit.
RHIC is currently operating but is set to cease operations in 2025.
A new Electron-Ion Collider is being built at the same lab, expected to provide fresh insights into atomic particles' structure and behavior, with construction set to finish by 2033.
Back to: The 2007 Avian Catastrophe: A Harbinger of Electromagnetic Disruption
The birds' navigational systems, overwhelmed by intense RF signal pulse waves, led to the migrating birds disorientation, panic, and ultimately, death.
This tragic event serves as a grim reminder of the consequences of unchecked electromagnetic pollution.
The Consequences of Disruption: A Symphony of Confusion
As RF-Signals permeate the environment, birds' navigational abilities are compromised, leading to:
- Disorientation: Birds become lost, unable to chart their courses, and struggle to find their way.
- Altered Migration Patterns: Changes in magnetic cues do indeed alter migration routes, leading to increased energy expenditure and reduced survival rates, tampering with the food chain of ecology.
- Collision Risks: Disoriented birds are more likely to collide with structures, such as arial planes, buildings or wind turbines, resulting in fatalities.
A Call to Action: Preserving the Avian Navigational Landscape
As we continue to harness the power of electromagnetic technology, it is essential to consider the unintended consequences on the natural world of ecology around us.
By acknowledging the impact of severe RF signals on avian navigation, we can work towards mitigating these effects and preserving the delicate balance of our ecosystem. This involves:
- Reducing RF Emissions: Implementing measures to minimize RF signal strength and exposure.
- Conservation Efforts: Protecting and restoring natural habitats, which can help birds adapt to changing environmental conditions.
- Research and Development: Encouraging further study on the effects of electromagnetic pollution on wildlife and developing strategies to mitigate these impacts.
The relationship between electromagnetic pollution and avian navigation is complicated indeed.
By recognizing these outlined consequences of RF signal pulse waves on bird migration and behavior, we can take steps to preserve the integrity of their species navigational systems and ensure the continued health of our planet's remarkable avian populations.]PVS: end.
The magnetoreception of birds vary as to mechanism.
Magnetoreception is actually a number of different ‘senses’. So the physical mechanism of magnetoreception varies. Apparently, different migrating birds evolved different forms of magnetoreception.
Magnetoreception is a general name for all senses where a magnetic field is the stimulus. However, there are many different mechanisms for magnetoreception.
Scientists have shown that different types of magnetoreception is most effective regarding geomagnetic fields.
So magnetoreception is primarily used for navigation. The magnetic field of the earth at a point is generally more than a thousand times greater than the magnetic field generated by a living thing.
So far as scientists can experimentally demonstrate at the current time, animals use magnetoreception for navigation.
There are two types of magnetoreception that has been demonstrated in birds.
Some bird have tiny ferromagnetic (e.g., iron) particles in the cells of their neck.
Some bird species use entangled pairs of electrons in a protein of their eyes.
Some birds have both. However, different nerve endings are involved in each form of magnetoreception, so one can hypothesize that the sensed qualia are different.
The birds that use the ferromagnetic particles DO NOT ‘see’ the magnetic fields. The particles are not in their eyes or optic nerve. These birds would feel the magnetic field even in the pitch dark.
The birds that use the entangled pair of electrons most probably see distortions in the image recorded with their eyes. These birds can not use their magnetoreception in the dark. The entangled photons in the cryptoprotein alter the photochemical reactions in the retina of the bird.
So one could could say that these birds see a vision auperimposed on whatever they see [like augmented reality smart-glasses].
These images would change primarily with the earth’s magnetic field, though.
The ‘vision’ is functionally like a traffic sign.
PVS: [The Role of Feathers in Native American Cultures
The Sacred Dance of Eagle Feathers: Unveiling the Esoteric Significance in Native American Culture
In the vast expanse of Native American spirituality, the eagle feather stands as a revered symbol, imbued with profound meaning and mystical significance.
Like the intricate patterns woven into a traditional basket, the use and honor of eagle feathers are deeply intertwined with the cultural and esoteric practices of Native American communities.
The Eagle's Gift: A Symbol of Spiritual Connection
Eagle feathers are considered a sacred gift from the Creator, embodying the qualities of strength, wisdom, and courage.
Like the eagle soaring high above the landscape, these feathers serve as a bridge between the physical and spiritual realms, connecting the individual to the divine.
In ceremonies and rituals, eagle feathers are used to convey prayers, honor the ancestors, and seek guidance from the spirits.
The Medicine of the Eagle: Healing and Protection
In Native American tradition, the eagle is revered for its healing properties and protective powers.
The feathers are believed to possess the medicine of the eagle, which can be used to ward off negative energies, bring balance to the individual, and facilitate spiritual growth.
Like a shield guarding against harm, the eagle feather is thought to offer protection and safeguard the wearer from malevolent forces.
The Art of Giving and Receiving: A Sacred Exchange
When eagle feathers are given or received, it is often within the context of a sacred exchange.
This exchange is akin to a ritualistic dance, where the giver and receiver engage in a ceremonial transaction that honors the feather's significance.
The recipient is expected to treat the feather with reverence, using it in a way that respects its spiritual power and the intentions of the giver.
The Feather's Significance in Ceremony: A Bridge to the Divine
In various Native American ceremonies, eagle feathers play a central role, serving as a conduit to the divine.
During the Sun Dance, for example, eagle feathers are used to connect the dancers to the spirits, while in the Sweat Lodge ceremony, they are believed to purify and protect the participants.
Like a key unlocking a hidden door, the eagle feather facilitates communication between the physical and spiritual worlds.
Honoring the Tradition: Respect and Reciprocity
The use and honor of eagle feathers are deeply rooted in respect and reciprocity.
Native American communities recognize the eagle's sacrifice and the spiritual significance of its feathers, which are often obtained through prayer and ceremony.
Like a promise kept, the feathers are treated with reverence, and their use is guided by a deep understanding of their esoteric significance.
The significance of eagle feathers in Native American culture is indeed magnificent and profound.
By exploring the esoteric dimensions of their use and honor, we gain insight into the rich spiritual multidimensional heritage of Native American communities and the enduring power of these sacred symbols.] PVS: end
Biomechanics of the Peacock's Display: How Feather Structure and Resonance Influence Multimodal Signaling
Courtship displays may serve as signals of the quality of motor performance, but little is known about the underlying biomechanics that determines both their signal content and costs.
Peacocks (Pavo cristatus) perform a complex, multimodal "train-rattling" display in which they court females by vibrating the iridescent feathers in their elaborate train ornament.
Here we study how feather biomechanics influences the performance of this display using a combination of field recordings and laboratory experiments.
Using high-speed video, we find that train-rattling peacocks stridulate their tail feathers against the train at 25.6 Hz, on average, generating a broadband, pulsating mechanical sound at that frequency.
Laboratory measurements demonstrate that arrays of peacock tail and train feathers have a broad resonant peak in their vibrational spectra at the range of frequencies used for train-rattling during the display, and the motion of feathers is just as expected for feathers shaking near resonance.
This indicates that peacocks are able to drive feather vibrations energetically efficiently over a relatively broad range of frequencies, enabling them to modulate the feather vibration frequency of their displays.
Using field data, it shows that peacocks with longer trains use slightly higher vibration frequencies on average, even though longer train feathers are heavier and have lower resonant frequencies.
Based on these results, we propose hypotheses for future studies of the function and energetics of this display that ask why its dynamic elements might attract and maintain female attention [the longer tail feathers, the more frequency, the more frequencies, the more dominant the male].
Finally, its demonstrated on how the mechanical structure of the train feathers affects the peacock's visual display by allowing the colorful iridescent eyespots-which strongly influence female mate choice-to remain nearly stationary against a dynamic iridescent background.
Many male hummingbirds produce loud sounds with their tail-feathers during their courtship displays.
Collaborator Chris Clark studies the aeroacoustics of how feathers flutter to produce sound.
Using Scanning Doppler Laser Vibrometer, we measured the vibrations of a series of hummingbird feathers in a wind tunnel, documenting how they vibrated as a function of feather size, shape, and airspeed.
It turns out that feathers can produce a wide variety of sounds, ranging in frequency, loudness, and harmonic structure. Interestingly, a vibrating feather can also interact with its neighboring feathers.
These interactions can amplify the sound, or they can produce interaction frequencies, if the feathers flutter at different frequencies.
Resonating feathers produce courtship song in rare bird, researchers report
Four years ago, a Cornell researcher reported a bizarre example of sexual selection in a rare South American bird:
The male attracts the female by rubbing specialized wing feathers, more than 100 cycles per second, to create a high vibratory hum, similar to a sustained violin note.
While the researchers speculated how the sound was created, they have since proven that the club-winged manakin's feathers resonate at a particular frequency to create the tone.
The adaptation is a striking example of a species modifying an essential body part for the purpose of attracting a mate.
"We normally don't think of sexual selection transforming areas of critical importance," said Kim Bostwick, curator of Cornell Museum of Vertebrates and lead author of a study published in the Nov. 11 issue of the Proceedings of the Royal Society.
The sparrow-sized, club-winged manakin has nine inner-wing feathers held adjacent by a ligament on each wing, but uniquely, the two innermost feathers, called the "sixth and seventh secondaries," have enlarged and hollow shafts.
The researchers found that when the enlarged sixth and seventh feathers are excited at their resonant frequency, an object's natural frequency of vibration, all nine hollow feathers resonate as a unit at 1500 Hertz to create the violinlike note close to an F-sharp.
The wing also produces a second harmonic tone at a similar or greater volume as the fundamental tone.
"These feathers have turned into a kind of tuning fork," Bostwick said.
The researchers discovered that all feathers naturally resonate at a frequency of 1500 Hz, but this weak resonance cannot be heard without such special adaptations as the enlarged hollow feathers of the male club-winged manakin, which create the audible tone that attracts females.
"The beginnings of that resonance already existed in the feathers," Bostwick said .
2007 RED-WING BLACK BIRDS DROPPING FROM THE SKY VIDEO: https://youtu.be/zUfRTA-hU4k?feature=shared