 Howdy partner, bruising through the Nidlis here book. Special news, it's definitely updated. Certainly not on a website that I'm looking at behind this book. It's in this book. Scientists, apparently have discovered the great pyramid, the great pyramid of can focus electromagnetic through it's hidden chambers. This here book, now some very famous, very courageous speculators such as Robert Bouvall and Graham Hancock. In the late, John speculated on the magnetic and electromagnetic, I guess that. Speculating that the great pyramid of Giza with its intricate, very precise, extremely precise mathematical characteristics was built to resonate electromagnetic emissions. Scientists on the 31st, this very day, just out back in Giza, Egypt have been using these fancy cosmic particles to probe the pyramid for certain electromagnetic characteristics. And they found that some of these certain frequencies, this monumental structure of the seven wonders of the ancient world, built five, maybe six thousand years ago, is apparently able to concentrate and amplify and resonate magnetic frequencies, and magnetic fields and electric fields. Retia, this is a pretty big breakthrough. The remarkable electromagnetic properties of the great pyramid of Giza could soon inspire nanoparticle designs for highly efficient. Scientists have found that the famous pyramid can concentrate electric and magnetic energy and blow its base, giving rise to distinct pockets of higher energy. Resonance, effect, certain geometric designs can amplify local area in space, constructive interference of the wave forms, radio waves of the electro, so while the 481 foot pyramid built thousands of years ago for Pharaoh Khufu has long drawn intrigue, purported mythical study is among a growing body of research attempting to finally get to the bottom of its physical properties. Egyptian pyramids have always attracted great attention. It says, Dr. Andrei Evliokin, scientific supervisor and coordinator of the research. He's quoted as saying, we as scientists, we're interested in them as well, so we decided to look at the great pyramid as a particle dissipating radio waves, as a particle dissipating radio waves resonantly. So that means it acts as a filter almost through which when radio waves pass they are manipulated, it's geometric. The researchers from ITMO University modeled the distribution of magnetic fields inside the pyramid, investigating the interactions with waves of resonant. Now, given the lack of reliable information about the pyramid's properties, the team says they did have to fill in some blanks and make some assumptions regarding its internal structures because it's been long thought the great pyramid actually contains hidden chambers. That word, they were sealed off. They actually tweeted my good buddy, their life. They researched this, but I was wondering if it, due to the resonant properties of it, any incoming cosmic radiation, I wonder if it could act as some sort of sensor for perhaps giving the Egyptians a warning or indication of incoming coronal mass ejection particles because although Earth has a boundary, a radiation deflects it, if you will, deflects the solar wind, and for the most part allows us to remain radiation-free on Earth, I think that maybe when it's too powerful, that's when you, for instance, see auroras. In the southern and northern pole times, there are particles that we've only been around writing history for a few thousand years. So perhaps this, perhaps there have been in the past maybe once in every hundred thousand years, once every 15,000, that would be enough for us not to have witnessed, observed a CME or coronal mass ejection in our life, civilizations, lifetime. Perhaps this could indeed detect and the Egyptians to run for safety. They, the researchers, assume that there were not any cavities inside for purposes of constructing an ideal model of the pyramid. With those assumptions, they obtained some interesting results that could find important practical applications. A multi-pole analysis shows that the pyramid concentrates electromagnetic energy in its hidden chambers. You can see at the top left, well, the top is electric and the distribution on the bottom row is magnetic fields. So we have volts per meter and this includes the chamber thought to contain ferrocufus remains in that made and that made for his wife along with a third, third unfinished chamber. When considering the pyramid on a substrate, such as limestone, the plateau upon which it was built, the researchers say it focuses the energy through the empty space to down to the substrate. You can kind of see that. Well, in the case of the pyramid on the substrate, at shorter wavelengths, the electromagnetic energy accumulates in the chambers providing local spectral maximum, which for electric and magnetic fields, which is just a fancy way of a scientific technical saying that that is where it peaks. So it is shown that basically the pyramid is the electromagnetic wave and then focuses them into the substrate region. So the region, you can see the multiple analysis shows the pyramid concentrates electromagnetic energy in its hidden chambers. Distributions of electric on the top row and magnetic again in free space are shown. So the discovery isn't just important for understanding of the agent. According to the researcher, the way electromagnetic energy distributes in the pyramid could actually make for an efficient particle design. And we're finding out even more about this magnificent structure, this incredible structure. Choosing material with suitable electromagnetic properties, we can obtain pyramidal nanoparticles with a promise for practical application in nanosensors and effective solar cells. Polina, Capitanova, the Faculty of Physics and Technology. ITMO University is one of Russia's leading higher education research institutes, information technology, optical design, and engineering. It's what they specialize in. Founded in 1900, so it goes way back. So the abstract, the actual paper submitted to the Journal of Applied Physics says electromagnetic properties of the Great Pyramid. First, multiple resonances in energy, concentration, and the abstract is that resonant response of the Great Pyramid interacting with external electromagnetic waves of the radio frequency range, which, like I said was 200, is theoretically investigated with the help of numerical simulations in multiple decomposition. It's found that, so I guess multiple just means when you have a dipole, that's two poles north and south. A monopole doesn't exist for magnets. Magnets always have two poles. So multiple I guess would be more than two, more than I have to suffice. So with the help of numerical simulations and monopole, multiple decomposition, I don't know what that is again. It's found that the spectra of the extinction and scattering cross-sections include resonant features associated with the excitation of the pyramid's electromagnetic dipole and quadrupole spectra of the extinction and scattering cross-sections include resonant features associated with the excitation. Okay. Moment, quadrupole and dipole moments is referring to the property of like levers but translated onto the theory of, I'd be lying if I said I could explain that. I learned it at one point and I just never used it. So it has to do with the particles that have a positive and negative pole, so dipole interacting with the overall electric field and magnetic field, they're intimately interlinked. And very generally they exist, the fields exist at right angles to one another. So if this was the electrical field oscillating like this, the magnetic field would be oscillating like this. Electron electromagnetic field distributions inside the pyramid at the resonant conditions are demonstrated and discussed for two cases. Remember this is still the abstract work. When the pyramid is located in a homogenous space or on a substrate, it's revealed that the pyramid's chambers can collect and concentrate electromagnetic energy for both the surrounding conditions. In the case of the pyramid on the substrate at shorter wavelengths, the electromagnetic energy accumulates in the chambers providing local spectral maxima for electric and magnetic fields. So that's at shorter wavelengths. So it expresses different characteristics when interacting with these particles, with these electromagnetic fields at different magnitudes, I guess. No, not magnitudes, different frequencies. If you're talking about wavelengths two to six hundred meters long in between crests, it's going to exhibit different characteristics than wavelengths longer or shorter radio wavelengths from maybe one, you know, a hundred to one meter or longer, you know, a thousand to ten thousand meters. So it's shown basically that the pyramid scatters the electromagnetic wave and focuses them into the substrate region. The spectral dependence of the focusing effect is now discussed. Yeah, so this article is actually, well, not article, because I guess even if you're a PhD in physics you're probably not doing a good job of explaining yourself if you have to only, if you can only write an explanation and articulate it to an audience of your peers. So the Egyptian pyramids are one of the wonders of the world they write in the paper here, which are of great interest to people far from science as well as researchers in various scientific fields, including history, archeology, architecture, and even physics and astronomy. Because, of course, that's why Robert Pofall and Graham Hancock were very first, I guess. They proposed with seriousness, very much sincerity, that the pyramids were meant to align with the Orion's Belt. And it's such a fascinating theory. And if you rewind the oscillation, the wobble of the Earth, the procession of the equinox, which completes a cycle every 26,000 years, Robert Pofall actually used a software, used a program to rewind what the night sky would look like until he found it to match the point at which, the point in time which ended up being about, I think, 11, or 9,000 years ago, or no, 9,000 BC, so like 11,000 years ago. And he saw that two things synced up. One was that the pyramids aligned with Orion's Belt directly overhead. And the other was that the sphinx actually lined up looking directly at the constellation Leo. So it's, you know, to the layman like me, it's very convincing. I'd like to see what... I'd like to see further explanation, exploration by experts in astronomy and archeology in geology like Robert Schock. So legends associated with these amazing structures excite the imagination of people engendering various fables and some baseless assumptions. This is especially true of the Great Pyramid. The largest and most complex from a structural point of view, the Pyramids, the Pyramids present on the plateau of Giza in Egypt. In this context, applications of modern physical methods and approaches for investigations of pyramidal properties are important and it could allow to make a new discovery or get new information motivating new interests to the Pyramids. For example, quite recently, cosmic ray muon radiography was used to discover a large void with a cross-section similar to the grand gallery in the one of the known voids, one of the known cavities or rooms in the pyramid. It's got a length of about 30 meters. So this large void appears to exist directly above the grand gallery, which constitutes the first major inner structure found in the Great Pyramid since. In this paper, we use another modern approach and consider the Great Pyramid as a physical object that could have resonant properties when interacting with external electromagnetic waves of the, specifically, of the radio frequency range with a corresponding wavelength. Looks like an upside-down y from 200 to 600 meters, as we said. We show that the observed resonant properties open the way to control the propagation and concentration of electromagnetic energy in the Pyramid's vicinity. Our investigations are based on numerical simulations of the total electromagnetic fields, that and total extinction, which is a technique realized in the CST Microwave Studio in ComSolve Multiphysics. That's an acronym, C-O-M-S-O-L, Multiphysics for Independent Tests Our results of our results, the method of discrete dipole approximation, or DDA, is used as well. The multiple moments and the multiple decomposition of the extinction and scattering cross-sections are calculated using the multiple decomposition of the extinction and scattering cross-sections, are calculated using the expressions for the Cartesian multiple moments obtained by the long wavelength approximation. As a result of our investigation, we find and explain a set of important features. Concerning the resonant concentration of electromagnetic energy by the Pyramid. Note that the method of the multiple analysis of electromagnetic waves scattering of electromagnetic waves scattering by physical objects is widely used in photonics to study the optical resonances of metal and dielectric nanoparticles. However, this approach can be effectively used in any electromagnetic spectral range if the wavelength of an incident wave, if the wavelength of an incident wave in the scattered dimensions are comparable. So if you're able to conduct an experiment which allows you to compare comparable the incident wave, which means the kind of baseline, you know, the known variable. So you have a wave and you understand its initial properties and then it kind of interacts or gets filtered through the Pyramid structure, which would be the who of the main objectives of our study in this paper are partial removing of unreasonable speculations about electromagnetic properties of the Great Pyramid and the demonstration of flexibility of the multiple decomposition method for research at both the nano, which is like and macro scales, which is... And then they go into the theoretical background with some very complex equations which relates the extinction cross-section in terms of which which tries to determine the extinction cross-section omega, or no, sorry. The cross-section is equal to the angular frequency of the incident monochromatic electromagnetic wave divided by 2 times the times the integral of the electric field, the incidental electric field, so the known electric field times and the dot product of the mathematical representation of the polarization. But let's go down to their conclusion and see what they concluded. These are extremely... This is so cool. Alright, so the conclusion will conclude. In this study we have considered electromagnetic excitation of the Great Pyramid by plane waves with the wavelengths being larger than the typical size of the scatterer. In this case only several first-order multiple resonances have been observed. The multiple analysis of electromagnetic waves and their scattering by the Great Pyramid has been performed in the radio frequency range and revealed important physical properties concerning the accumulation and focusing of electromagnetic energy. It has been shown that the Pyramid can resonantly scatter electromagnetic waves and support resonant excitation of electromagnetic multi-poles which resulted in the strong electromagnetic fields inside the... So for the Pyramid located in free space we have demonstrated that the total total extinction cross-section does not depend on the considered incident conditions. The magnetic field distributions inside the Pyramid are different for the same wavelengths leads to the different multiple decompositions for the both considered incident conditions. For the Pyramid located on the substrate we found that it basically scatters electro-bocuses and scatters the focusing effect by saying the obtained results can be considered as a first step for further investigation of the Pyramid and geometries. As one example we can now study the complex system of the Pyramids and investigate if they're inside a magnetic field big enough, concept of a higher order means that in general you have interactions between two waves say you see a wave and sometimes one wave there's different sets out there of waves that come in every few minutes or every 15 minutes and they're clearly coming from different sources from perfectly so that they... you'll see the wave basically one or two of them will actually double will be about double the size of the average waves that you've been seeing come in times they're exactly all are exactly pretty much destructive