New Scientific discoveries about
the Great Pyramid of Giza shows electro-magnetic fields and anomalies, (using thermal scanning, Muons cosmic particles, and multipole
analysis.)
http://www.dailymail.co.uk/sciencetech/article-6008131/Great-Pyramid-Giza-focus-electromagnetic-energy-hidden-chambers.html
The Great Pyramid, also known as Khufu's Pyramid, is the
sole survivor
of the ancient Seven Wonders of the World
For more than 4,500
years, Egypt's pyramids have kept their secrets hidden deep within the
labyrinth of passages and chambers that lie inside their towering stone
structures.
But the long-running
row over whether the Great Pyramid of Giza is hiding a network of
previously undiscovered tunnels behind its stone walls has now been
answered. The researchers confirmed the find using
cosmic particles known as muons to scan the Great Pyramid of Giza. They used the scans to create maps to reveal the
internal structure of the 479 feet (146m) high pyramid.
Last year
thermal scanning identified a major anomaly in the Great Pyramid, the largest and oldest of the pyramids at Giza and
one of the seven Wonders of the Ancient World. Those scans identified three
adjacent stones at its base which registered higher temperatures than others.
Those scans identified three adjacent stones at its base which registered
higher temperatures than others. This led to theories that they
may be hiding a secret chamber that had yet to be discovered.
Scientists discover Great Pyramid of Giza can focus electromagnetic energy through its hidden chambers
- New analysis shows pyramid concentrates electromagnetic energy in chambers
- This includes two chambers inside, and a third unfinished one beneath the base
- Scientists say breakthrough could lead to more efficient nanoparticle designs
The
remarkable electromagnetic properties of the Great Pyramid of Giza could soon
inspire nanoparticle designs for highly-efficient sensors and solar cells.
Scientists have discovered the famous pyramid
concentrates electric and magnetic energy into its internal chambers and below
its base, creating pockets of higher energy. If this concentrating effect is able
to be recreated on a nanoscale size, it could lead to a wave of new, more
efficient sensors and solar cells, the researchers claim.
While
the 481-foot pyramid built
thousands of years ago for Pharaoh Khufu has long drawn intrigue for its
purported mythical qualities, the study is among a growing body of research
attempting to finally get to the bottom of its physical properties.
Scientists have found that the
famous Great Pyramid of Giza can concentrate electric and magnetic energy in
its chambers and below its base, giving rise to distinct pockets of higher
energy
‘Egyptian
pyramids have always attracted great attention,’ says Dr Andrey Evlyukhin,
scientific supervisor and coordinator of the research. ‘We as scientists were
interested in them as well, so we decided to look at the Great Pyramid as a
particle dissipating radio waves resonantly.’ The international research team
looked into the relationship between the shape of the Great Pyramid of Giza and
its ability to focus electromagnetic energy.
To
do this, the team led by ITMO University in Saint Petersburg, Russia,
created a model of the pyramid, one of the seven wonders of the ancient world,
to accurately measure it electromagnetic response. The researchers used
the model to see how wave energy is scattered or absorbed by the pyramid. They
tested the interactions with waves of resonant length, ranging from 200 to
600 metres (656ft to 1,968ft).
Given
the lack of reliable information about the pyramid’s properties, however, the
team says they had to fill in the blanks for some factors. ‘We had to use
some assumptions,’ Evlyukhin admitted. ‘For example, we assumed that there
are no unknown cavities inside, and the building material with the properties
of an ordinary limestone is evenly distributed in and out of the pyramid. ‘With these assumptions made, we obtained
interesting results that can find important practical applications.’
Scientists
used multipole analysis – a method widely-used in physics to study the
interaction between a complex object and electromagnetic field – to reveal how
the pyramid concentrates electromagnetic energy into in its underground
chambers. This includes the
two chambers believed to have contained the remains of Pharaoh Khufu and his
wife, as well as the third unfinished chamber buried beneath the base.
A multipole analysis shows the pyramid concentrates electromagnetic energy in its hidden chambers. The distributions of electric (a)–(e) and magnetic (f)–(j) field magnitude in the Pyramid and its supporting substrate is shown above.
The Ancient Egyptians that built the
pyramids more than 4,400 years ago were not aware of this quirk of design. However, researchers now believe
the relationship between the design of the pyramid and its ability to focus
wave energy through to its core could play a hugely-important for nanoparticle
research in the future. When considering the pyramid on a substrate – such as
the limestone plateau – the researchers say it focuses the energy through the
empty spaces to the substrate. ‘In the case of the Pyramid on the substrate, at
the shorter wavelengths, the electromagnetic energy accumulates in the chambers
providing local spectral maxima for electric and magnetic fields,’ the
researchers wrote in the study.
‘It
is shown that basically the
Pyramid scatters the electromagnetic waves and focuses them in to the substrate
region.’
A multipole analysis shows the pyramid
concentrates electromagnetic energy in its hidden chambers. Distributions of electric (top row) and magnetic (bottom row) field
magnitudes in the free space are shown.
While
the 481-foot pyramid built thousands of years ago for Pharaoh Khufu has long
drawn intrigue for its purported mythical qualities, the study is among a growing
body of research attempting to finally get to the bottom of its physical
properties
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