Revealing the Electromagnetic Characteristics of the Great Pyramid of Giza
Studies indicate that the ancient structure can focus electromagnetic energy.
Recent research has revealed that the Great Pyramid of Giza can concentrate electromagnetic energy within its inner chambers and underneath its base.
An international team of researchers employed theoretical physics methods to explore the pyramid's interaction with electromagnetic waves, specifically in the radio frequency spectrum.
Their results suggest that under certain resonance conditions, the pyramid can focus electromagnetic energy in specific locations, including the King's Chamber, the Queen's Chamber, and the unfinished chamber beneath the structure.
These conclusions were drawn from numerical modeling and analytical techniques.
The researchers initially estimated that resonances in the pyramid could be excited by radio waves with wavelengths between 200 and 600 meters.
They then modeled the pyramid's electromagnetic response and calculated the extinction cross-section to assess how much of the incoming wave energy might be scattered or absorbed under resonant conditions.
Ultimately, they mapped the electromagnetic field distribution within the pyramid for these parameters.
The authors of the study propose that these findings could guide the creation of nanoparticles capable of achieving similar effects in the optical range, which might lead to innovations in nanosensors and highly efficient solar cells.
Furthermore, engineer Christopher Dunn has suggested that the Great Pyramid functioned as a large acoustic device, harmonically linked to the Earth.
In his book, 'The Giza Power Plant: Technologies of Ancient Egypt,' Dunn theorizes that the pyramid was engineered to transform the Earth’s vibrational energies into microwave radiation.
He argues that the various chambers and passageways of the structure were strategically positioned to enhance its acoustic properties.
While these ideas present fascinating views on the pyramid's function, they continue to be topics of discussion and debate within the scientific community.
An international team of researchers employed theoretical physics methods to explore the pyramid's interaction with electromagnetic waves, specifically in the radio frequency spectrum.
Their results suggest that under certain resonance conditions, the pyramid can focus electromagnetic energy in specific locations, including the King's Chamber, the Queen's Chamber, and the unfinished chamber beneath the structure.
These conclusions were drawn from numerical modeling and analytical techniques.
The researchers initially estimated that resonances in the pyramid could be excited by radio waves with wavelengths between 200 and 600 meters.
They then modeled the pyramid's electromagnetic response and calculated the extinction cross-section to assess how much of the incoming wave energy might be scattered or absorbed under resonant conditions.
Ultimately, they mapped the electromagnetic field distribution within the pyramid for these parameters.
The authors of the study propose that these findings could guide the creation of nanoparticles capable of achieving similar effects in the optical range, which might lead to innovations in nanosensors and highly efficient solar cells.
Furthermore, engineer Christopher Dunn has suggested that the Great Pyramid functioned as a large acoustic device, harmonically linked to the Earth.
In his book, 'The Giza Power Plant: Technologies of Ancient Egypt,' Dunn theorizes that the pyramid was engineered to transform the Earth’s vibrational energies into microwave radiation.
He argues that the various chambers and passageways of the structure were strategically positioned to enhance its acoustic properties.
While these ideas present fascinating views on the pyramid's function, they continue to be topics of discussion and debate within the scientific community.
