FIELD COMPRESSION ENERGY STORAGE (FCES)

Every major research institution and battery company is chasing a single number: 500-1000Wh/kg.

Billions are being poured into lithium-sulfur, solid-state, sodium-ion, lithium-air and graphene enhanced chemistries, all trying to break through the limits of electrochemical energy storage

WHY:

Because the most advanced batteries today are stuck at 250-350Wh/kg

Lead-acid, iMH, Lithium Ion, Solid-State. They all rely on electrochemical redox reactions. Capacitors, Ultra capacitors and super capacitors store energy electrostatically. Solid State batteries use solid electrolytes for ion transport and safer, denser charge cycles.

They all work by moving ions or storing charge between electrodes and through an electrolyte. 

And while they differ in safety, cost, and power delivery... they are all constrained by the fundamental physics of matter-based storage.

Rather than relying on electrochemical or electrostatic methods, the Positron Faraday stores usable electricity within a dynamically stabilized energy field. The field acts as a persistent medium, compressing and retaining energy that can be extracted and regulated on demand.

Field Compression Energy Storage (FCES) operates on the principle of capturing and stabilizing energy within a dynamically modulated field, and then rectifying it into continuous, regulated power — similar in concept to how high-frequency energy can be converted into direct current. However, FCES is not harvesting ambient waves, nor is it limited by electromagnetic capture physics. It is an internally stabilized energy structure.

This persistent field — once compressed and stabilized — becomes a reliable, high-availability energy reservoir that can be directed with precision. One of the most transformative applications of this is in multi-charging cycles for conventional rechargeable cells.

Traditional rechargeable batteries, such as lithium-ion cells, store energy electrochemically and are rated by their static energy density — often around 250 Wh/kg. This rating reflects a single charge-discharge cycle and does not consider dynamic recharging while in operation.

With FCES, however, we are no longer limited to one cycle at a time.

The FCES field can continuously maintain batteries and power cells  in a near-perfect state of charge recovery, even as they power a load.

This allows the same batteries to perform as though they are being constantly refilled, significantly extending the number of usable hours per gram — and therefore the effective or extrapolated energy density of the battery.

From 250Wh/kg to thousands of Wh/kg. Let's say a 1kg lithium-ion battery is rated at 250 Wh/kg. It discharges its 250 Wh and would then need recharging. If powered by a wall outlet or other external form of charging, it gets recharged once and repeats.

That same battery can be continuously cycled — charged, discharged, and recharged — hundreds or thousands of times (depending on its life cycle), on a live loop. If the battery is maintained for 1,000 hours delivering 100 watts, it outputs 100,000 Wh. For that same 1 kg battery, this equates to an extrapolated energy density of 100,000 Wh/kg — not because the battery holds more, but because the FCES field keeps it replenished with minimal loss.

This doesn’t violate thermodynamic limits or imply perpetual energy. Rather, it elevates the system architecture: FCES acts as a continuous, non-invasive energy source.

The power cell becomes a buffer — not the primary reservoir.

This method preserves the simplicity and infrastructure of lithium-ion and other rechargeable batteries and power cells while giving them field-backed super-performance.

Field Compression Energy Storage not only stores energy in a fundamentally new way — it transforms how traditional batteries behave. By continuously charging cells from a stabilized field, FCES elevates the functional energy density of existing technologies from hundreds to tens of thousands of Wh/kg. It makes batteries last longer, work harder, and deliver exponentially more — without changing their chemistry.

• Lithium-Ion ~ 250 Wh/kg
• Solid-State ~ 400-500 Wh/kg
• Sodium Ion ~ 160 Wh/kg
• Tesla 4680 ~ 300 Wh/kg
• Positron FCES ~ 100,000Wh/kg +