eThrust is a digital foundry engineering the next generation of HTS magnets — from 2G REBCO windings to 4G 3D-printed superconductors. Powering fusion reactors, space thrusters, MRI machines, and beyond.
The world we are working to build — and the conviction that drives every decision we make.
We believe superconducting magnets will become the foundational technology of the 21st century. eThrust exists to accelerate that transition across every industry that demands extreme performance.
Through 3D printing and advanced deposition technologies, we eliminate the design constraints that have held superconductor engineering back for decades — unlocking entirely new classes of HTS products.
We are building the platform — the materials science, the processes, and the products — that will power a superconducting world across every sector that demands extreme field performance.
We close the gap between fundamental superconductor research and deployed commercial products — translating laboratory breakthroughs into reliable, field-ready engineering systems.
To accelerate the global transition to high-field applications by engineering the next generation of HTS magnets. We bypass the limitations of traditional manufacturing through 3D-printing and no-insulation technologies, delivering compact, quench-safe, and extreme-field solutions.
Drive the global shift from conventional electromagnets to high-temperature superconducting systems — faster, at lower cost, and at the scale that meaningful technological change demands.
Leverage 3D-printing and no-insulation winding to shatter design constraints — opening geometries and performance regimes previously out of reach for HTS magnet engineering.
Deliver magnets with intrinsic quench protection through NI winding architecture — eliminating the single greatest reliability concern in HTS deployment.
Push the achievable boundaries of magnetic field strength — engineering solutions that operate where conventional magnets simply cannot.
Deliver 50%+ mass reduction over first-generation designs, enabling HTS technology to reach platforms where weight and volume have historically been prohibitive barriers.
Bridge the gap between academic superconductor research and deployable commercial products — ensuring that scientific breakthroughs translate into reliable, field-ready engineering systems.
Three generations of HTS magnet technology — from production-ready REBCO windings to the frontier of additive superconductor manufacturing.
Production-grade HTS magnets with 26.86 T demonstrated field. Quench-safe NI winding. 50% lighter than 1G systems.
From igniting artificial suns to propelling spacecraft through the void — our superconducting magnets are the silent engine behind humanity's most ambitious technology.
HTS magnets are the linchpin of compact tokamak and stellarator fusion reactors. They generate the immense magnetic fields needed to confine superheated plasma at over 100 million °C.
eThrust's NI-wound REBCO coils provide the field strength, stability, and compactness that makes privately-funded fusion viable. At 26.86 T, our 2G magnets are well within the range required for breakeven plasma confinement in compact designs.
2G REBCO coils achieving 26.86 T — sufficient for compact fusion confinement
Single-phase cryocooling — no liquid helium infrastructure required
NI winding eliminates catastrophic quench failure modes critical in fusion environments
A superconducting flux pump injects DC current into a closed superconducting circuit without electrical contact — eliminating resistive connections that generate heat and compromise cryogenic performance.
eThrust HTS magnets serve as core persistent-mode magnets in flux pump systems, maintaining stable magnetic fields indefinitely. Our NI winding architecture accommodates current redistribution without localised heating.
Contactless current injection — all resistive heat sources eliminated from the cold circuit
Once charged, REBCO coils maintain field with essentially zero decay for days or indefinitely
NI winding enables safe redistribution of current flux essential for pump-integrated designs
Superconducting motors achieve power densities 3–5× higher than conventional motors while operating at near-perfect efficiency. By replacing copper stators with HTS coils, losses drop to near-zero — producing extraordinary torque from compact, lightweight assemblies.
eThrust's 3G laser-printed coils, conforming to curved motor geometries, are particularly well-suited to the next generation of axial-flux and radial-flux HTS machines.
HTS motors achieve 3–5× higher power density versus copper-wound equivalents at the same weight
Superconducting windings eliminate I²R losses — approaching theoretical peak motor efficiency
Laser-printed coils conform to curved stator surfaces — enabling novel axial-flux machine designs
The Applied-Field Magnetoplasmadynamic Thruster (AFMPDT) delivers high specific impulse for efficient long-duration deep-space missions. Performance scales directly with applied magnetic field strength.
eThrust's compact 26 kg REBCO coil assemblies provide the powerful applied field at a fraction of conventional coil mass — a critical advantage where every kilogram determines mission feasibility.
50% lighter than first-generation systems — critical for launch mass budgets on deep-space missions
Higher applied field directly improves AFMPDT Isp — reducing propellant mass for deep-space missions
No liquid helium required — standard space-grade cryocoolers maintain operating temperature on-orbit
NMR spectroscopy is the gold standard for molecular structure determination in chemistry, biochemistry, and pharmaceutical research. Resolution scales with magnetic field — and eThrust HTS magnets reach the extreme fields that the most demanding research demands.
Our 2G REBCO coils support NMR systems up to 1.3 GHz (30.5 T equivalent). Persistent-mode operation ensures ultra-low field drift for multi-hour acquisition experiments.
Equivalent to 30.5 T — resolving protein structures at the frontier of biophysical research
Persistent-mode stability enables multi-hour NMR acquisitions without field-lock drift
Places eThrust coils among the highest-field NMR-capable magnets available commercially
eThrust REBCO coils serve as the active element in resistive Superconducting Fault Current Limiters (SFCLs), transitioning from superconducting to resistive state within microseconds of a fault — faster than any mechanical breaker.
HTS cables carry 5–10× more current than copper at the same diameter, enabling city-scale power corridors in existing conduits. Our compact 2G architecture is ideal for urban grid retrofits.
SFCL transition limits fault currents before equipment damage — faster than any mechanical breaker
HTS cables carry 5–10× more current than copper at equivalent cross-section
Superconducting transmission lines eliminate I²R heating — recovering GWh annually
With eThrust HTS technology, fields of 11.7 T and beyond become achievable in compact systems — revealing sub-millimetre anatomy, metabolic activity, and molecular biomarkers invisible to conventional scanners.
The reduced footprint versus liquid-helium-cooled systems makes ultra-high-field MRI in hospital settings a realistic proposition. Persistent-mode operation ensures field homogeneity below 1 ppm.
Fields from 7 T to 11.7 T+ unlocking sub-millimetre imaging resolution for neuroscience
Persistent-mode REBCO coils achieve <1 ppm homogeneity for clinical-grade imaging
No liquid helium — enabling high-field MRI deployment in standard hospital facilities
Superconducting maglev achieves levitation through the Meissner effect — HTS coils expel magnetic flux, creating stable levitation without active control. This enables frictionless, near-silent transport exceeding 600 km/h.
eThrust's compact HTS coil assemblies serve as onboard levitation and propulsion magnets in next-generation maglev vehicles with substantially reduced cryogenic system mass versus traditional LTS maglev.
HTS maglev removes mechanical friction entirely, enabling commercially viable hypervelocity transit
Flux-pinning enables passive, stable levitation without active feedback control systems
Laser-printed 3G coils conform to complex geometries — ideal for advanced linear motor integration
The minds behind eThrust — engineers, scientists, and visionaries building the superconducting future.
We're building the team that will build the future.
We are assembling a team of the most driven engineers, physicists, and innovators on the planet. If you want to work on technology that matters at the deepest level — this is it.
Join the eThrust team as a full-time engineer, researcher, or technology professional. We are looking for people as obsessed with superconductors as we are.
We offer competitive compensation, equity participation, and the rare opportunity to work on technology that will shape the next century.
We actively seek research collaborations, industrial partnerships, and investment relationships with organisations that share our ambition to deploy superconducting technology at scale.
Whether you need custom magnets, co-development, licensing, or co-investment — we are open to conversations about shaping the superconducting future together.
Whether you need a custom magnet system, want to explore a partnership, or are ready to join the team — we want to hear from you.
We aim to respond to all enquiries within 48 hours. For urgent technical or partnership discussions, please mark your subject line accordingly.