"ENERGY NEUTRINO" - free technology of power generation

2024 Author: Seth Attwood | [email protected]. Last modified: 2023-12-16 15:55

In connection with global climate changes in recent decades, caused, among other things, by an irresponsible and shortsighted way of human life, the question of the development of new technologies and the creation of new materials that provide not only a comfortable life for a person, but also can radically reduce the negative impact of human life on own habitat.

The impact of human activity on the climate is a multicomponent and very complex topic, including both the disposal of human waste and the refusal to burn fossil fuels to generate electricity and use it for internal combustion engines.

There has long been a discussion in the scientific community about how real the generation of electricity from cosmic neutrino particles is. One side positively asserts that the flux of cosmic neutrinos through the Earth's surface is stable day and night, regardless of the weather and time of year, and if scientists have learned how to get electricity from the visible spectrum of radiation (sunlight), then it is possible to get current from the invisible spectrum of radiation (such as cosmic neutrinos) or other types of radiation. And the question is only in the creation of new materials that would allow converting the energy of neutrinos into electric current.

Pessimists argue that although the Nobel Prize in Physics was awarded in 2015 for proof of the fact that neutrinos have mass, this mass is very small (much lighter than electrons). “If we postulate that energy can be obtained from neutrinos, then two questions arise: at what price and will it be practical? Simply put, technical and economic feasibility must be demonstrated, says Professor Yehia Khalil, Yale University, USA and Research Fellow, University of Oxford, UK. He is joined by Jacques Roturier from the University of Bordeaux - “The Ice Cube Experiment is another excellent demonstration of the extremely small interaction of neutrinos with matter. Yes, some energy is transferred in this process. But there is no chance of getting enough energy to generate electricity even to cook one egg. But are scientists theorists who study mainly the fundamental foundations of neutrino physics, and not their applied applications, so right?

It should be noted that in recent years a lot of publications have appeared describing the research carried out on this topic. And when analyzing the publications of scientists from different countries, we can conclude that the way to use cosmic neutrinos to generate energy lies in the creation of materials with increased atomic vibration. In Nature, ETH (Eidgen? Ssische Technische Hochschule, Z? Rich) professor Vanessa Wood and her colleagues explain what processes cause atomic vibrations when materials are nanosized, and how this knowledge can be used to systematically develop nanomaterials for a variety of applications. The publication shows that when materials are manufactured in sizes less than 10–20 nanometers, that is, 5000 times thinner than a human hair, the vibrations of the outer atomic layers on the surface of the nanoparticles are large and play an important role in how the material behaves. All materials are made up of atoms that vibrate. These atomic vibrations, or "phonons", are responsible for how electrical charge and heat are transferred in materials.

At the same time, the use of graphene nanostructures in the creation of new technologies is attracting the closest attention. But in order to better understand modern materials such as graphene nanostructures and improve them for devices in opto-, nano- and quantum technologies, it is important to understand how phonons - the vibration of atoms in solids - affect the properties of materials. The work just published shows that scientists from the University of Vienna, the Advanced Institute of Science and Technology (AIST) in Japan, JEOL and La Sapienza University in Rome have developed a technique that can measure all phonons present in a nanostructured material. Thus, for the first time, they were able to establish all vibrational modes of autonomous graphene, as well as the local expansion of various vibrational modes in graphene nanofibers. This new method, which they called "large-q mapping," opens up entirely new possibilities for establishing spatial and impulsive phonon expansion in all nanostructured as well as two-dimensional modern materials. These experiments open up new possibilities for studying local vibration modes on the nanometer scale down to specific monolayers.

Schematic representation of local lattice vibrations in graphene, excited by the wavefront of transmitted fast electrons. (Image credit: © Ryosuke Senga, AIST)

However, scientists from the Neutrino Energy Group under the leadership of the German mathematician and businessman Holger Schubart have advanced farthest in the practical implementation of the latest developments in graphene-based materials for energy generation. Using many years of theoretical and practical developments, a multilayer coating material with nanoscale thickness based on doped graphene and silicon was created, capable of generating direct current under the influence of not only cosmic neutrinos, but also other types of radiation, such as electrosmog, for example. Doping of the coating layers was carried out to increase atomic vibrations.

Under the influence of cosmic high-energy neutrinos and other radiation, atomic vibrations are amplified, leading to resonance, which is transferred to the metal foil, and the resulting energy is converted into electrical energy. Moreover, for the transition from atomic vibrations to resonance, it is enough to receive very little energy from cosmic neutrinos thanks to the created multilayer innovative material.

Regarding the comments of Professor Yehia Khalil mentioned above, the Scientific Council of the Neutrino Energy Group notes the following: “In our estimate, the cost of producing this type of energy will be significantly less than 50% of the cost of producing other types of energy, and on a really large industrial scale much more profitable."

In addition, the power source is very compact and does not require operating and maintenance costs. For example, a sheet of foil of size A-4, covered with a special dense layer of doped nanoparticles, provides a stable output electrical power under laboratory conditions of 2.5-3.0 W. NEUTRINO POWER CUBE®, designed to generate electricity with a capacity of 4.5 to 5.5 kW / h, will have a compact size of a "diplomat".

The principle of operation can be compared to photovoltaic cells, where light (visible radiation spectrum) is converted into energy. The main advantage and difference of NEUTRINO POWER CUBE® lies in the fact that energy can be generated continuously 24 hours a day, since the background radiation (invisible radiation spectrum) reaches the Earth even in complete darkness.

Such dimensions and output data allow the Neutrino Power Cube® neutrino current source to be widely used in various devices and equipment, up to use in electric vehicles and industrial power generation.

Commenting on the intense debate in the scientific community and the press, Neutrino Energy Group CEO Holger Schubart criticizes the extent to which the public remains in the dark, despite the fact that the current state of knowledge in the field of neutrino particle physics offers real possibilities for solving modern problems with completely new approaches … “Particles of the invisible spectrum of radiation are certainly able to supply people with more energy day after day than any of the dwindling fossil resources around the world,” - say the company's scientists. In their opinion, current research should focus on this huge energy field above us, which we will need to use in the future, instead of continuing to "dig the earth."

Despite the fact that the Neutrino Energy Group is a German - American research alliance, Holger Schubart criticizes the situation in Germany: “Germany is lagging behind in global applied research. Significant discoveries in the field of neutrino physics have not yet come to the German research environment - unlike the United States and many other countries of the world, where they already belong to recognized knowledge. Of course, it would be interesting to know where the neutrinos came from, and, of course, it is very interesting to document neutrino movements at the South Pole - practically on the other side of the world - and sometimes "catch" at least one particle, but THIS should NOT be a priority in using millions "Research" means - the true goal of science must not be overlooked - this goal, according to Schubart, is to search for and gain practical knowledge in order to make the world a better place, and in this particular case, to find an opportunity to use the high-energy invisible spectrum of solar and cosmic radiation to generate energy.

More detailed information can be obtained: