⚡ Dynamic Magnetic Control
Magnetic systems have always treated flux as something to resist, contain, or bleed away. FluxWorx takes the opposite view: magnetic energy is a resource — a medium that can be guided, shaped, routed, and reused with intent.
Where classical magnetics fights its own fields, our Magnetic Transistor manages them with purpose.
Flux is guided instead of fought. A controlled magnetic circuit instead of a stressed one.
💡 What Is the Magnetic Transistor?
The Magnetic Transistor is the first practical device that steers magnetic flux with minimal loss. Instead of forcing the core toward saturation, the geometry guides flux along controlled, low-stress paths that reduce hysteresis and heating.
Not blocking. Not saturating. Not wasting energy as heat.
It operates by giving magnetic flux preferred pathways—low-reluctance routes that act like directional channels.
Flux that cannot do useful work in one region is smoothly diverted to another, or parked in a controlled reservoir, without distortion or bulging.
Where traditional components wrestle their own fields into compliance, the Magnetic Transistor guides them.
This creates magnetic circuits that stay linear, predictable, and cool… even under conditions that normally drive cores into chaos.
The result isn’t a new trick — it’s a new class of component. A magnetic counterpart to the electronic transistor: a true control element built at the physics layer.
🧬 How It Works — The Physics Layer
Magnetic flux always follows the path of least reluctance — the magnetic analogue of resistance. Change the geometry of those paths, and you change where the flux wants to go.
That’s the entire foundation of the Magnetic Transistor.
We create a magnetic structure where the geometry creates a directional reluctance preference under bias, producing asymmetric flux distribution.
Reverse the applied field, and the circuit no longer offers an equivalent return path — the reluctance landscape has shifted.
Instead of forcing the field to reverse through a saturated or inefficient pathway, the Magnetic Transistor diverts it into a controlled side-route, or diverted into a low-reluctance bypass branch that completes the magnetic circuit without loading the primary path.
There’s no blocking. No brute force. No collapsing coils or runaway saturation.
Just physics doing the work:
• Forward direction: a preferred, low-reluctance path for forward flux.
• Reverse direction: A higher-reluctance gate that redirects, not resists
• Side channel: A stable reservoir where unused flux can rest without heating the system
The device never fights the field — it shepherds it. This keeps flux contained, eliminates bulging at boundaries, and avoids the chaotic nonlinearity that normally appears near saturation.
Because the mechanism relies on geometry rather than exotic materials, it scales effortlessly across ten orders of magnitude:
• Ferrite blocks on the bench • Laminated cores at kilowatt scale
• Soft-magnetic tracks on a chip carrying only a few gauss
Where classical magnetics sees a fixed outcome, the Magnetic Transistor introduces choice into the flux pathway — a directional preference built directly into the magnetic circuit.
That’s the transistor effect.
🎯 Why It Matters — Tangible Results
High-Performance EV Drives 🏎️
Permanent-magnet motors hit a hard ceiling at high speed because the magnets’ fixed field becomes the enemy. Field-weakening burns heat, wastes copper, and erodes efficiency.
A Magnetic Transistor gives motors their first low-loss, geometry-assisted field-weakening mechanism:
• Higher sustained speed
• Lower operating temperatures
• Reduced drag torque • Quieter, smoother behaviour
• Real-world range improvements in EV platforms
This is field control without throwing watts away.
Simpler, Cheaper, More Reliable Electronics 🔌
Every inverter and converter wrestles magnetic behaviour inside its inductors, transformers, and chokes. Losses pile up. Switching stresses climb. Thermal budgets balloon.
By managing flux inside the core itself, the Magnetic Transistor allows:
• Smaller, leaner power stages
• Lower switching losses
• Reduced thermal stress
• Longer component lifespan
• Lower total system cost
Flux routing inside the core reduces stress on switching stages and simplifies the magnetic workload they manage.
⚡ High-Power DC Fault Control
DC faults don’t give you a zero-crossing. They surge fast, hit hard, and destroy expensive hardware in microseconds.
A Magnetic Transistor acts as a magnetic check-valve, strongly favouring forward energy movement and resisting backflow.
This opens pathways to:
• Faster, cleaner protection schemes
• Smaller and lighter protection stacks
• Higher reliability in DC grids, EV platforms, aerospace buses
• Lower mechanical and thermal burden on breakers
Fault control becomes more elegant — and more survivable.
🖥️ Magnetic Logic & Secure Computing
Because the transistor effect works at single-digit gauss, the same geometry-driven mechanism scales to micron-level magnetic tracks.
That enables:
• Radiation-immune magnetic logic
• Non-volatile routing elements
• Secure computation with no semiconductor leakage
• Operation in high-EMI, high-temperature environments
🌐 A Platform Technology
One device. Multiple domains. No exotic materials. Manufacturable today.
Immediate applications span:
• Motors & generators
• Power routing & converters
• Aerospace & defence magnetics
• Adaptive magnetic shielding
• Sensors & actuators
• On-chip logic
• Industrial automation
• Energy storage & UPS systems
Wherever flux exists, control matters — and until now, there’s never been a component built for that job.
🛡️ Validation & Progress
The Magnetic Transistor isn’t theoretical. It’s modelled, demonstrated, protected — and moving fast toward institutional testing.
📜 IP Protection
Three Australian provisional patents are already filed (March, May, July 2025).
The consolidated PCT application is scheduled for early 2026 and will fold the transistor effect, the flux-steering geometry, and system-level embodiments into a unified filing.
All disclosures, videos, and public material are aligned with these provisionals and safe under their priority dates.
📊 Modelling & Simulation
Independent FEA and FEMM simulations confirm the directional-transistor effect across:.
• ferrites, steels, and soft-magnetic composites
• multiple geometries
• both high-gauss and low-gauss operating regimes
• chip-scale and kilowatt-scale structures
The same physics holds at every scale — a key differentiator from spintronic magnetic diodes, which remain constrained to nanometre films and low-energy digital switching.
Upcoming uploads will include:
• FEMM field maps
• reluctance plots
• directional asymmetry visualisations
• multi-material cross-verification results
All modelling is reproducible and will be provided as a package for institutional review.
🔬 Experimental Demonstration
Our bench prototype shows clean, real-time flux steering using:
• dual-end Hall measurements
• magnetic film visualisation
• controlled forward vs. reverse response
• an external flux source for repeatability
The upcoming December video demonstrates unambiguous transistor action: forward preference, reverse suppression, and controlled diversion.
🤖 Independent Review
Two independent AI research systems — Gemini 3 Pro and ChatGPT 5.1 — have reviewed the patent materials and prior art.
Their findings:
These AI analyses screen for overlaps in published patents and literature. They do not validate physical performance; they confirm that the geometric transistor effect does not appear in known spintronic or classical magnetic-circuit prior art.
🧑🔧 Expert Endorsement
A senior electrical engineer with nearly fifty years of experience reviewed the core architecture and simply asked:
“How the hell did you think of this?”
🚀 Where We Are Now
FluxWorx is entering the next phase:
• institutional validation (partner university)
• prototype refinement
• FEMM package release
• full PCT draft
• investor outreach
• on-chip low-gauss modelling
This is a foundation technology — a new control element for magnetic systems of every scale.
Download our White Paper HERE