A few years ago, lots of people believed that neutrino energy was just a form of science fiction, and many thought that our present technology would not be able to produce one. There were also people who claimed that our physical capabilities were limited and insufficient to create and harness neutrino energy. However, everything changed as scientists discovered new ways to translate invisible particle interactions into usable electricity, and this development quickly became news around the world. Today, the Neutrino® Energy Group has consolidated this knowledge into a precise mathematical framework, the Holger Thorsten Schubart–NEG Master Equation for Neutrinovoltaics, which provides the scientific foundation for the technology’s transition into reality.
In 2015, Takaaki Kajita, a scientist from Japan, and Arthur B. McDonald, a physicist from Canada, discovered that neutrinos have mass. Neutrinos are one of the smallest cosmic particles, previously thought to be massless, but theoretical speculation and precise measurements confirmed otherwise. Kajita and McDonald developed mechanisms to establish this crucial property, and their research, independently conducted yet converging on the same conclusion, earned them the Nobel Prize in Physics. This discovery validated that neutrinos carry energy, sparking widespread interest in their potential. At the time, however, the broader public paid little attention to the significance, and the practical implications were still obscure.
Neutrinos are considered as particles with a high-energy supply, and they keep on reaching Earth without any abrupt end. These particles are invisible to the naked eye, and humans would not be able to perceive them, unlike the light spectrum which produces different colors. The discovery that these tiny particles have mass is essential to the scientific community because it has the potential to become an infinite energy source. Those who believe that they could be an energy source cite the Theory of Relativity by Albert Einstein. They claimed that the theory’s most famous equation, E=mc², states that anything that has mass must contain energy. Scientists have been experimenting with this for years, and under special conditions, they managed to create a measurable portion of energy. The skepticism has always been there, and researchers working on this field were often mocked, with critics stating that the energy produced would be unusable or non-existent. Despite the negative views, the scientific milestones are clear: the Nobel Prize in Physics in 2015 confirmed that neutrinos have mass, and the COHERENT collaboration in 2017 experimentally verified coherent elastic neutrino–nucleus scattering (CEνNS), proving that neutrinos impart measurable momentum to matter. More recently, astrophysical data from the James Webb Space Telescope and ALMA in 2025 reaffirmed the critical role neutrinos play in stellar energy transport. With these confirmations, the energy potential of neutrinos is not illusion but physics.
Supporters of the technology surrounding neutrinos compare its development to solar energy. Just as photovoltaics harvest visible light, neutrinovoltaic technology transforms the invisible spectrum into electrical current. The principle is similar in concept but different in mechanism: neutrinovoltaic systems do not capture particles, but instead use multilayer nanostructures of doped graphene and silicon that resonate under neutrino–electron scattering, CEνNS, non-standard quark interactions, cosmic muons, ambient RF fields, thermal fluctuations, and mechanical micro-vibrations. These vibrations induce an electromotive force, harvested as direct current. Unlike solar cells, this technology operates independently of daylight or weather. The governing science is consolidated in the Holger Thorsten Schubart–NEG Master Equation for Neutrinovoltaics:
P(t) = η · ∫V Φ_eff(r,t) · σ_eff(E) dV. This formula defines how effective flux densities, scattering cross-sections, and conversion efficiencies translate invisible fluxes into usable current.
Scientists of the Neutrino® Energy Group, founded and led by mathematician Holger Thorsten Schubart, are at the center of this transformation. Their work builds on international collaborations in particle physics and material science, uniting breakthroughs into practical engineering. The Group’s devices, based on neutrinovoltaic principles, are designed first for small electronics, such as powering mobile phones, and then scaled upward. The Neutrino Power Cube is one such system: a compact, autonomous generator providing continuous electricity without reliance on grids. It is scalable by design. For example, 200,000 Power Cubes correspond to approximately 1,000 MW of output, equivalent to the capacity of a mid-sized nuclear plant, but distributed in decentralized units. Alongside the Power Cube, the Neutrino Life Cube extends the concept to household and community-scale supply. Both represent a shift from centralized generation to distributed resilience.
REVOLUTIONARY BREAKTHROUGHS
REGARDING NEUTRINO RESEARCH
The vision extends further into mobility and communication. Under the umbrella of Pi Mobility, the Neutrino® Energy Group is developing applications that embed neutrinovoltaic composites into vehicles. The Pi Car generates part of its own driving electricity from invisible spectra, reducing dependence on charging infrastructure. Pi Fly adapts the principle for aviation, providing constant support for avionics and endurance. Pi Nautic applies it to maritime systems, supplying auxiliary power on board and reducing reliance on fossil-fueled generators. All three concepts symbolize a transport sector no longer constrained by plugs, grids, or fuel depots.
Complementing hardware, the Group has launched blockchain-based instruments NET8 and Pi-12, which create the financial and digital infrastructure for licensing, integration, and cooperative development. These tokens serve as economic anchors, ensuring that neutrinovoltaics is not only a scientific achievement but also a structured, scalable ecosystem. Project 12742 pushes further, exploring neutrino-based communication technologies across planetary scales, linking energy science to the future of global data transfer.
Harnessing neutrinos for their energy will change the world drastically, providing us with a future full of opportunities. The new technology will not only reduce fossil reliance but also support a more resilient, decentralized energy system. With the Power Cube, Life Cube, Pi Mobility, and blockchain integration, an entire architecture of energy independence emerges. Centuries of industrialization have produced irreversible damages to the environment, but neutrinovoltaics offers a path of mitigation: clean, continuous, always-on electricity, rooted in rigorously validated physics. While critics once dismissed the field, the consolidation of experimental evidence, the formulation of the Master Equation, and the construction of prototypes mark a decisive shift. The path forward is no longer abstract. It is calculated, engineered, and ready to scale.
According to project blueprints, these energy sources will be delivered in modular units, making energy supply flexible and geographically independent. Instead of massive infrastructure where power is generated centrally and transmitted over long distances, neutrinovoltaic systems generate electricity exactly where it is consumed. This reduces losses, eliminates bottlenecks, and bypasses the need for vast transmission expansion. The Master Equation ensures that the energy flow is continuous, as all invisible fluxes contribute additively, with no single point of dependency.
Third, communication systems could be improved with the harnessing of neutrinos. Electromagnetic radiation has been the traditional medium for transmitting communication, but it has its limitations. For example, seawater interferes with efficient communication with submerged nuclear submarines. Yet, neutrinos easily pass through seawater, which would make them an idea carrier of communication. While physicists have long theorized that neutrino-based communication was possible, it was not proven possible until a 2012 experiment at Fermilab in Batavia, Illinois. Researchers there used the lab’s neutrino beam projector to transmit the word “neutrino” 1 km.
