Artificial intelligence (AI) has driven the rapid development of data centers. At the same time, demand for electricity from consumers and various sectors of the economy is growing. This is driven by the increasing number of homes, vehicles, and industrial processes switching to electric power. Since large nuclear power plants take up to 10 years to build, plans are underway worldwide to build hundreds of gas-fired power plants to meet the growing demand for electricity, which will increase significantly with the development of AI-powered data centers. However, a shortage of turbines for these power plants could lead to a new energy crisis. Gas generation, unlike renewable energy, is characterized by its stability, which led to record gas demand last year.

According to Bloomberg, gas-fired power plants worth more than $400 billion are planned to be commissioned by the end of this decade. However, these projects face the risk of delays or cancellation due to a shortage of turbine capacity. The main problem is that there are only three key manufacturers of the largest turbines used in power plants: Siemens Energy, GE Vernova, and Mitsubishi Heavy. These companies are either unable or unwilling to expand their production capacity quickly enough to meet growing demand. Germany alone plans to build up to 20 new gas-fired power plants by 2030, while Chinese energy companies are actively promoting the country's development plan for the next five years in Beijing. They seek approval for the construction of new gas-fired power plants, with a capacity of approximately 70 gigawatts by the end of the decade.

At first glance, the development of solar and wind energy seems a logical solution to the problem of increasing generating capacity. However, experience shows that these energy sources are unstable and dependent on the weather. Furthermore, their stable operation requires expensive energy storage systems.

Proponents of traditional technologies may make the most compelling arguments, but the future of energy inevitably lies in non-fuel sources. Since the work of Nikola Tesla, scientists have attempted to generate electricity using ambient radiation fields. Only now can we confidently state that a solution to this highly complex problem has been found by a team of researchers and engineers from the Neutrino Energy group, led by mathematician and president Holger Thorsten Schubart. They have succeeded in creating a multilayer nanomaterial consisting of alternating layers of graphene and doped silicon deposited on a metal foil. Quantum-mechanical calculations and molecular dynamics modeling enabled the selection of a structure with alternating layers of graphene and doped silicon. Every parameter was carefully selected to maximize power generation.

Holger Thorsten Schubart, President of the Neutrino Energy Group

The work, which had been ongoing for nearly two decades, has accelerated in recent years thanks to the use of AI in calculations. This has eliminated the need for lengthy experimental work. For theoretical calculations, the concept of "power element" dP(t) was introduced. It measures the power generated by a volume dV. This indicator depends on the energy absorption efficiency η, the ambient flow Φ_{amb}(r,t), and the effective cross-section σ_{amb}(E):

dP(t)= η · Ф_{amb}(r,t)· σ_{amb}(E)·dV

Integrating over the entire generating volume V, we obtain the total instantaneous power according to the basic equation for neutrinovoltaics: “Schubart Master Formel NEG”:

P(t) = ʃ · η (r,t) · Φ_{amb}(r,t) · σ_{amb}(E) · dV

Tests showed that solar neutrinos provide 58% of the energy, cosmic muons 32%, and electromagnetic waves and heat 10%. This combination ensures power generation fluctuations of less than 5%, guaranteeing stable generation day and night, in any weather, even in underground garages and building basements.

Discussions about the possibility of generating energy from neutrinos have been ongoing for many years. A series of experiments were conducted to confirm the potential of this approach. Tests at a depth of 1,000 meters in a salt mine, where electromagnetic waves and muons are shielded, showed that the module's output power dropped to 58%. This corresponds to the energy contribution of neutrinos. In a chamber with a lead shield, which blocks muons, the power dropped to 65%. This corresponds to a 32% contribution from muons. These results indicate that neutrinos are indeed an important energy source.

It's important to note that the Neutrino Power Cube energy module is a resonator-energy converter, and the module itself does not generate any radiation. Tests conducted by the German Federal Office for Radiation Protection show that the radiation dose rate around the module is no different from that in the natural environment and significantly below international safety limits. Due to the absence of rotating parts, the module produces no noise during operation.

Cost is the main factor determining the successful implementation of neutrino technology in everyday life. To move the neutrino system from the laboratory to mass production, the Neutrino Energy group of companies joined forces with leading research centers, enabling the creation of not only a scientific base but also a production line. As a result, the cost per kilowatt-hour has already been reduced from €1.21 to €0.018, making it competitive with traditional photovoltaic and wind power.

A decentralized demonstration power plant with a total capacity of 1 GW is planned for construction by 2028. This power is generated by approximately 200,000 Neutrino Power Cubes, each of which provides 5 kW of continuous power:

200,000 × 5 kW = 1,000,000 kW = 1 GW

This doesn't mean commissioning a large-scale central power plant, but rather creating a grid-independent, decentralized energy system that puts into practice the core idea of ​​neutrinovoltaics—energy autonomy at any point.

"Neutrino energy promises to eliminate geographic and climatic barriers to access to energy resources," states Holger Thorsten Schubart. In a future where every building and car can generate energy, humanity will be freed from dependence on fossil fuels and centralized grids. This will open the door to energy independence.

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