Technology

Our Technology

At MAQNION MBH, we are building a new approach to clean energy by combining two advanced fields: Quantum Fusion and Quantum Energy Teleportation (QET).

Quantum Fusion focuses on how energy is generated — using quantum-enhanced fusion to create a cleaner and more powerful energy source.

Quantum Energy Teleportation (QET) focuses on how that energy is transferred — enabling direct, wireless energy delivery using principles from quantum physics.

Together, these innovations form the foundation of our energy system: one that is clean, efficient, modular, and ready for the future.

This section explains both technologies in simple terms, compares them to current approaches, and shows why our solution works — with real results to support it.

What is nuclear Fusion?

Nuclear fusion is the process where two light atomic nuclei combine to form a heavier nucleus, releasing a massive amount of energy. It’s the same reaction that powers the sun and stars.

The released energy can be captured and converted into electricity through heat (this part is similar to an atomic fission plant). Or said energy can directly be converted into electricity (through a process not unlike Einstein’s photoelectric effect).

Other technologies:

Nuclear fission: splitting heavy atoms to generate energy.

Disadvantages: Expensive to build, radiation hazards, pollution of spent nuclear fuels.

Solar Energy: Einstein’s “photoelectric effect, converting light into electricity.

Disadvantages: Expensive, takes up large amounts of space, pollution through discarded panels

Wind power: Wind driven turbines generate electricity through a dynamo kind effect.

Disadvantages: Expensive to build and maintain, not always generating power, large waste impact when discarded.

Oil, gas, coal: Burn fossil fuels generates heat, turned into steam, generating electricity.

Disadvantages: greenhouse gasses, inefficient conversion cycle (40% efficiency at best).

How nuclear Fusion works?

Fusion occurs when light elements, typically isotopes of hydrogen like deuterium and tritium, are heated to extremely high temperatures—creating a plasma. Under these intense conditions, the nuclei have enough energy to overcome their natural repulsion and fuse together.

This fusion releases energy, which can be captured in two main ways:

Thermal conversion, where the heat is used to produce steam and drive turbines—like in traditional power plants.
Direct conversion, where energy is turned straight into electricity using advanced methods inspired by the photoelectric effect.

To achieve fusion on Earth, scientists use powerful magnetic fields or laser-based systems to contain and control the super-hot plasma where fusion happens. The fuel—such as deuterium—is readily available, and the process produces no greenhouse gases, no long-lived radioactive waste, and is inherently safe, as the reaction naturally shuts down if the required conditions aren’t met.

Why is nuclear fusion better:

Green energy, virtually unlimited power.
No radiation or nuclear waste.
Cheaper to build, faster to implement to generate useful energy.

Current Fusion Technologies attempted

Current attempts had yet to field a useful electricity generating design. A famous monicker for fusion was that the technology was always “30-years away”. Below a quick overview of current state of affairs and why MAQNION technology succeeded where others struggle so far:

MAGNETIC CONFINEMENT

This technology relies on large volumes of plasma (Tokamak or Stellarator), heated to hundreds of millions of degrees, in an attempt to increase the chance of atoms fusing together, hoping to generate useful electricity form this process. The problems with this technology are, but not limited to:

Important in size and therefore requiring huge magnetic and radio frequency force to heat such an important volume of plasma to over 100 million degrees C. The power input of such installations is so large that, even if they would work, one can wonder if the output power would exceed the input.
Operates at the very limits, and often exceeds, state of the art material sciences.
Very capital intensive, hard to modify when the initial design doesn’t work or science progresses.

INERTIAL CONFINEMENT

Almost at the opposite of “magnetic confinement”, usually involves imploding a very small target of fuel (so-called “Hohlraum”) to generate energy, either through powerful lasers or some electrostatic device.

Lasers used are the size of a football field, using up Megawatts of power. Although this works, it is mostly destined for research and not energy generation.
Hard to sustain actual electricity generation as one would have to inject fuel “pellets” into the device dozens of times per second.
Extremely expensive, some of the technologies required not available to anything but government agencies.

Why does MAQNION “Quantum Fusion” work?

Current attempts had yet to field a useful electricity generating design. A famous quip for fusion is that “Fusion technology is always 30-years away.” MAQNION went in a radically different technological direction, by recognizing the fundamental quantum physics nature of nuclear fusion itself. Quantum meaning the infinitesimally small, the minimum a human can measure (and smaller).

Overview: Current state of affairs and why MAQNION technology succeeded, where others struggle so far:

Instead of using exterior forces to discipline plasma (nigh impossible), we used the natural binding force of quantum mechanics itself to achieve unprecedented compression of a fuel plasma to burning fusion conditions like inside a star.
Where others aim to obtain fusion in volumes of several to hundreds of cubic meters, or implode small pellets with Petawatts of laser power, the MAQNION design compresses a 5GW/sec energy “reservoir” into a sphere of merely 12 microns in diameter. At such a density, the distance between fuel ions is 3-6 femtometer (1fm = 1E-15 meter), and fusion becomes inevitable, thanks to the high tunnelling probability (>90%), at such distances.
The system works because hundreds of thousands of individual ion beams are focused into an extremely small volume. This would normally create a repulsive force (charge effect) but that is countered through the extremely fast rotation the precise injection gives to the this fuel sphere. Normally here a centrifugal force would counter this compression, but the density is such that local gravity dominates any centrifugal outward force. Quantum physics and general relativity, quite naturally, become the dominating mechanisms under such conditions.
Here a natural “dynamo effect” occurs and generates a huge local magnetic field and gravity (> 20 times that of earth), compressing the fusion volume without any external energy input required. The same quantum mechanical dynamo effect that occurs in neutron stars, hence the nickname “Magnetar” for this fusion technology.
The volume is so dense that the fuel volume’s local Spacetime curvature itself is twisted, through the fast rotation and “Frame Dragging”. The plasma volume starts acting under the laws of General Relativity, rather than Newtonian physics. Hence, any “classical” physics effects are strongly diminished, if even still relevant.
The success of our approach was not “we need a bigger reactor, laser or magnet”, but rather focusing on the quantum physics that start dominating when taking fusion technology at the (almost) individual ion level, as opposed to any of the current statistical bulk fusion approaches.

MAQNION “Quantum Fusion”; The Proof

At GMBH, we have developed a new kind of nuclear fusion technology that works in a completely different way than traditional methods:

Instead of heating large amounts of gas to extreme temperatures, we control individual atoms with high precision.
We send hundreds of thousands of tiny fuel beams into a small, fast-spinning zone only 12 microns wide—that’s smaller than a human hair.
In this tiny space, the atoms are pulled very close together—closer than in the core of the Sun.
At such close distances, fusion happens naturally and reliably, without needing extreme pressure or heat.
The system works because because we follow the rules of quantum physics, not the old-school Newton laws.

What makes it powerful:

More control, less waste: We don’t waste energy managing chaotic plasma—we use precision.
Efficient energy: The energy from fusion is turned into electricity using heat and other advanced methods.
Clean fuel: We use hydrogen-based fuels, which are safe, easy to get, and found even in seawater.
It works: We have already demonstrated the technology in the lab, and it's now operational in the field. We are no longer talking about future potential — the systems are built, deployed, and delivering power today.
A new era: This is not just a new machine—it’s a smarter way of doing fusion. Think of it like moving from steam engines to microchips.

This is the fundamental reason for the success of the MAQNION “Magnetar” design: General Relativity and quantum mechanics as the dominant frame of reference NOT traditional Newtonian physics.

QET: “Quantum Energy Teleportation”

Quantum Energy Teleportation (QET) focuses on the delivery side of energy. Instead of relying on wires, transformers, or long-distance transmission lines, QET uses quantum phenomena to move energy from one place to another. This allows for energy distribution that is direct, wireless, and instantaneous — even over long distances.

Can energy be teleported? The answer is “Yes”, in a quantum system it is possible. Actually, quantum computers use this principle every day but it is called “Quantum Information Teleportation”.

The basis for this is a correlation between particles, no matter how remote, called “entanglement”, whatever happens to one particle is instantly known to the entangled twin and it takes the “opposite” value.

Think of it as a person giving Alice and Bob both a box with a coin, one contains a Euro, the other a Dollar. Alice travels to New York and Bob goes to Tokyo. Neither of them know what is in their box. In the quantum world this is called a “superposition of states” (the infamous Schrödinger Cat), Alice and Bob therefore have both at the same time, as long as the box remains closed. Alice now opens her box and sees a Dollar, therefore instantly knowing that Bob must have a Euro in his, no matter how far away he went.

Does breaks general relativity however? Because it seems that this information travelled faster than the speed of light… No it does not, because Bob will not know until Alice sends him a message (LOCC - Local Observation Classical Communication), to inform him what is in his box, and that message can never go faster than the speed of light. Causality is maintained and the information is “teleported”. Energy can be transported in the same way.

How does this work with a MAQNION “Magnetar” reactor?

At the reactor level, the energy is “observed” (one can think of it as a photograph. This information is transmitted (via classical internet) to the remote QET location where the same message is implemented again, and the available energy is extracted as electricity, without any radiation, even if the reactor is thousands of miles away. This is made possible through what are called “quantum vacuum fields”, entangled (correlated) dimensions of space time, connecting all of the universe, regardless of distance.

It is this fundamental characteristic of our world that makes it possible to transmit energy at unparalleled efficiencies (>75% as opposed to current 40% technology), without radiation, influence of distance or weather.

This patented technology also makes the MAQNION fusion technology far superior to any other fusion approach. In other approaches, as was demonstrated before, the system relies on heating or recuperating kinetic particles, to generate electricity. This however is very inefficient as most of the available fusion energy is in the quantum fields that are not used by such systems. With QET, MAQNION makes an “image” of ALL of the available energy, therefore bringing an infinite reservoir of power to the table.

Advantages of nuclear Fusion as a source of Electricity

Nuclear fusion offers a wealth of benefits that make it the ideal energy solution for the future:

No radiation, no radioactive waste products produced.
Green energy, limitless and without any emissions (Helium being the only matter produced by the reaction).
Cheaper “to grid” per kW than any other current technology.
Nuclear fission: 10 years to implement, heavy regulatory aspects, > 7,000 USD/kW capital costs.
Solar, Wind: Large footprint, environmental impact: >750 USD/kW capital costs.
Oil, gas, coal: Important pollution impact, >2,000 USD/kW.
Deployable: Its small form factor allows for a quick installation even in remote and hostile locations or disaster areas.
Technology is inherently safe, runaway reactor physically impossible.
No fuel scarcity: Fusion uses isotopes of hydrogen, which are abundant—even available from seawater.
Reliable baseload power: Unlike solar or wind, fusion can run 24/7 without depending on weather conditions.
Minimal land use: Compact fusion reactors require far less space than wind or solar farms.
Scalable: From small modular units to large-scale infrastructure, fusion systems can be tailored to demand.
Low maintenance and long life: Few moving parts, no corrosion or combustion, leading to longer operating cycles and lower upkeep.