Europe · Switzerland
Deutelio
Magnetic confinement — levitated dipole
Magnetic
Deuterium-Deuterium (D-D)
Undisclosed
TBD
Investor brief
Levitated dipole fusion on tritium-free D-D fuel
Executive Summary
Deutelio is a Swiss levitated-dipole fusion concept targeting deuterium-deuterium fuel — abundant, tritium-free, but requiring higher temperatures than D-T. A superconducting ring suspended in vacuum produces a naturally turbulence-suppressing magnetic field inspired by planetary magnetospheres.
Strategic Thesis
A levitated superconducting ring produces a naturally turbulence-suppressing field; D-D fuel removes the entire tritium logistics problem.
The Problem
Global electricity demand is entering an unprecedented growth phase driven by AI infrastructure, data centers, transport electrification, industrial decarbonization, water desalination, and advanced manufacturing. Solar suffers intermittency, wind capacity-factor variability, natural gas carbon emissions, conventional nuclear cost and deployment speed, and batteries energy-density and duration limits. The world requires a new source of clean, dispatchable baseload energy. Fusion represents the ultimate energy source — the challenge is making it commercially practical.
Levitated Dipole Reactor (D-D)
A free-floating superconducting ring produces a dipole magnetic field whose natural plasma equilibrium is remarkably stable — the same physics that confines Jupiter's radiation belts.
Levitated Superconducting Ring
A magnetically suspended superconducting ring inside the vacuum vessel produces the confining dipole field.
D-D Operation
Deuterium-only operation removes the tritium logistics, breeding blanket and most of the radioactive inventory of a D-T plant.
Turbulence Suppression
The dipole equilibrium is inherently stable against the drift instabilities that limit tokamak confinement.
Fuel Strategy
Deuterium-Deuterium
Tritium-free at the cost of ~10× ignition temperature relative to D-T.
Product Platform
Levitated Dipole Concept
Concept and magnet R&D toward a dipole demonstrator.
Energy Conversion
Thermal + partial Direct
Mixed
35–45% electrical
D-D fusion releases roughly half its energy in charged particles (potentially direct-convertible) and half in 2.45 MeV neutrons (thermal recovery only).
Conversion chain
- 1D-D plasma
- 2Charged products (T, ³He, p) → partial direct conversion
- 32.45 MeV neutrons → blanket → heat
- 4Combined thermal + electrical output
No tritium fuel supply problem and softer neutrons than D-T, but lower cross-section means higher confinement requirements.
Economic Vision
Eliminating tritium logistics, breeding blankets, and most regulatory burden dramatically simplifies the balance of plant — the trade-off is much higher plasma performance requirements.
Vision
Fusion power without tritium, on naturally stable plasmas.
Mission
Prove that the levitated dipole can do D-D fusion at engineering scale.
Engineering Bottlenecks
- Levitating superconducting ring uptime
- D-D ignition temperature (~10× D-T)
The description above reflects Deutelio's publicly stated technology goals, roadmap and architecture. Many elements — particularly net-energy gain at scale, advanced fuel cycles, and grid-relevant economics — remain ambitious objectives that have not yet been demonstrated commercially anywhere in the fusion industry. Forward-looking statements should be treated as engineering targets, not certainties.
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Citations & Sources
Academic & financial rigor- [01]
The Global Fusion Industry in 2025
Fusion Industry Association · Jul 2025
- [02]
Company disclosures and press releases
Deutelio
- [03]
Peer-reviewed plasma physics literature
Journal of Plasma Physics / Nuclear Fusion