The universe is a highly concentrated energy space, where subatomic particles serve as a continuous power source. As a result, the Earth appears to be a much more "open" system than previously thought. Neutrinos were previously viewed as "ghost particles" not involved in real interactions. However, their potential for energy generation points to a more intense and coordinated interaction with matter, particularly with graphene nanostructures, than traditional theories of particle physics predicted.

In classical physics, neutrinos are particles that easily pass through entire planets. The concept of a fuel-free power generation technology called Neutrinovoltaic, developed by the Neutrino Energy group led by mathematician Holger Thorsten Schubart, aroused skepticism among many traditional physicists, as it seemed improbable that something barely detectable could be used. The name immediately triggered the defense mechanisms of conventional science, before the mathematical formulas or resonance effects in graphene were investigated.

It should be noted that the technology was developed experimentally. However, after the publication of information about its creation, the scientists faced a wave of criticism from mainstream scientists, prompting the question of a theoretical justification for generating electricity from invisible radiation particles. This justification was fully formulated by the end of 2025, based on the scattered experimental and theoretical studies of independent scientists published by that time. The greatest contribution to substantiating the theoretical feasibility of Neutrinovoltaic power generation was the systematization of data obtained in the following studies:

Coherent Elastic Neutrino Nucleus Scattering (CEνNS): Neutrinos have an extremely weak ability to interact with matter. During the time it takes a neutrino to travel the diameter of the Earth, it collides with atoms only once. The discovery of CEνNS revealed a measurable physical process by which neutrino energy is transferred to an atomic nucleus. This mechanism is based on the principle of coherent addition of scattering amplitudes, significantly increasing the probability of interaction. As a result, the target nucleus gains momentum and additional energy.

The JUNO 2025 (Jiangmen Underground Neutrino Observatory) experiment was conducted to precisely measure neutrino fluxes, spectra, and interactions, as well as the oscillation parameters of solar and reactor neutrinos. Measurement accuracy reaches 3% at an energy of 1 MeV. Furthermore, the experiment allows for the quantitative determination of the number of scattering events per unit time per unit area.

The fundamental formula for Neutrinovoltaic technology, developed by the Neutrino Energy group, was derived by mathematician Holger Thorsten Schubart based on the principles of quantum and statistical mechanics. This formula is the key link connecting the action of microscopic particles with the generation of macroscopic energy.

The formula takes into account:

•       Ф_{eff} - the effective flux of invisible radiation;

•       σ_{eff} - the effective interaction cross section;

•       η - the energy absorption efficiency;

•       The geometry and density of the graphene and doped silicon layers;

•       Resonant amplification of microvibrations;

•       Electron mobility in P-N junctions.

The core of Neutrinovoltaic technology is a multilayer material made of alternating 2D layers of graphene and doped silicon, which acts as an energy converter. It operates at the quantum excitation level, using phonons, plasma exciters, and electrons. Its main advantages are revealed in three key areas:

1. In this technology, energy transfer is independent of macroscopic gradients. Energy is transferred through a local momentum flow and an energy flow, which is ensured by the density of quantized events.

Transfer occurs in discrete "portions"—quantum transitions between system states. The frequency of these events determines the power of the energy flow. This eliminates the collective motion of macroscopic objects, significantly reducing macroscopic losses such as friction, thermal conductivity, and energy dissipation in material defects.

2. The high interfacial density in multilayer structures implies the maximum number of interfaces between layers per unit volume. This leads to an increase in the area of ​​active surfaces that interact with particles such as neutrinos and nuclei. As a result, energy processes are concentrated at the nanoscale. Parallel bonds play a key role in this process. Each atomic layer in such a structure acts as an active element. Neutrino scattering, nuclear interactions, and energy transfer through lattice vibrations occur through planar parallel bonds rather than traditional point bonds. This significantly increases the energy capture efficiency per unit volume. The special architecture of the material, characterized by multilayered structure and parallel bonds, significantly improves energy capture efficiency.

3. The coherent propagation of quantized vibrations is an important property. Microscopic vibrations, such as phonons and plasma excitons, can travel significant distances in two-dimensional conducting materials, including graphene. This opens the possibility of superposition and amplification of multiple microscopic effects, overcoming the limitations associated with the low energy of individual events.

The energy of particles, fields, and invisible radiation is converted into electric current through the piezoelectric, triboelectric, and flexoelectric effects occurring in multilayer materials.

The transition from macroscopic motion to microquantum superposition is the main difference between Neutrinovoltaic technology and other energy generation methods. This offers undeniable potential and advantages that have not yet been tapped to create an innovative technology for generating clean and safe energy for all.

Authors: Holger Thorsten Schubart, L.K. Rumiantcev

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