Fig.3. The vibrations of atoms in materials, "phonons", are responsible for how electrical charge and heat are transferred in materials. (Graphics: Denise Bozigit / ETH Zurich).

 

Therefore, adherence to the graphene deposition technology is a key technological challenge, especially on wafers larger than 100x100 mm.Graphene has an extremely high electric current density (a million times greater than that of copper) and record carrier mobility. In graphene, each atom is bonded to 3 other carbon atoms in a 2D plane, with one electron remaining freely available in the 3rd dimension for electron conduction.In an interview with Research Frontiers, Professor Thibado (University of Arkansas) stated: “This is the key to using the movement of 2D materials as a source of inexhaustible energy. Tandem vibrations cause ripples in the graphene sheet, which allows you to extract energy from the surrounding space using the latest nanotechnology. Graphene films are surprisingly strong and elastic. Graphene has a very high thermal conductivity, which, combined with its high electrical conductivity, allows the passage of an electric current a million times higher than the maximum possible current in copper films. At elevated temperatures, according to the Fermi-Dirac distribution, some of the electrons pass into the conduction band, and "holes" remain in the valence band. This determines the fairly high electrical conductivity of graphene at room temperature. Conduction electrons and “holes” in graphene have zero effective mass, i.e. they cannot be stationary, but move all the time with the "Fermi velocity", which in graphene is about 106 m/s, that is, it is already relativistic. This determines the very high mobility of charge carriers in graphene, at least two orders of magnitude higher than their mobility in silicon, and the “ballistic” nature of their motion over the film. The mean free path of conduction electrons and holes in graphene at room temperature exceeds 1 μm.Harmonic vibrations of "graphene waves" turning into resonance, in fact, is the work done, necessary to convert the thermal (Brownian) motion of graphene atoms and the energy of particles of the surrounding fields of radiation of the invisible spectrum, including the kinetic energy of neutral neutrino particles, into electric current. As in the currently produced power generators installed at power plants, the developed Bedini power generation circuits and other fuelless power generation magnetic motor circuits, the occurrence of an electromotive force (EMF) occurs in each layer of graphene due to the interaction of magnetic and electric fields. However, the cardinal difference lies in the fact that in Neutrinovoltaic technology the pulsating mechanism of interaction arises not as a result of rotation of the rotor with a magnetic coil, but in the process of microvibrations of graphene in a nanomaterial, which is another physical principle of the emergence of EMF. The emf that arises in each layer of graphene causes electrons to flow in one direction, i.e. an electric current occurs. The movement of electrons in one direction is achieved by applying film coatings of each layer with alloying elements that create a p-n junction that passes electric current in only one direction, i.e. a thin-film diode effect occurs. The multilayer nature of the nanomaterial provides a solution to the problem of obtaining the maximum possible electrical power from a unit surface, since one layer of graphene cannot provide sufficient power for industrial applications.

 

Influence of neithrino on the process of oscillations of the "graphene wave"

 

​In 2019, information was published that scientists at the Karlsruhe Institute of Technology (KIT) managed to determine the mass of neutrinos with unprecedented accuracy. According to KIT, a neutrino is at least 500,000 times lighter than an electron; the particle mass is about 1.1 electron volts.The mechanism of interaction between neutrinos and matter was discovered and described in the publications of the COHERENT collaboration at the Oak Ridge National Laboratory (USA). Low-energy neutrinos have been shown to interact weakly with argon nuclei. This process is called coherent elastic neutrino-nuclear scattering (CEvNS). A neutrino, like a tennis ball hitting a bowling ball, hits the large and heavy nucleus of an atom and transfers a tiny amount of energy to it. As a result, the core almost imperceptibly bounces off (Fig. 4).