Capacitors in the Aetheric Magnetic Substrate

Capacitors in the Aetheric Magnetic Substrate (AMS) Ontology

1. What a Capacitor Is (AMS View)

In the AMS ontology, a capacitor is not a device that stores charge or energy inside matter.

A capacitor is a device that stores a spatial configuration of AMS tension between two separated conductor geometries.

Specifically:

  • Two conductors impose opposing boundary conditions on the AMS.
  • The dielectric region between them prevents direct torsional equalisation.
  • The AMS is therefore forced into a held, spatially extended tension gradient.

A capacitor stores geometry, not substance.

2. Capacitor Geometry as a Tension Trap

Consider a parallel-plate capacitor:

  • The plates are large, closely spaced conductors.
  • When connected to a voltage source:
    • One plate enforces a higher AMS tension boundary.
    • The other enforces a lower AMS tension boundary.
  • The dielectric prevents vorton slip between the plates.

Result:

  • The AMS between the plates is forced into a compressed, aligned tension field.
  • This configuration persists after the source is removed.

Key point:

The stored “energy” is the maintained deformation of the AMS in space.

Nothing is “inside” the plates except constraints.

3. Role of the Dielectric (Crucial Insight)

In AMS terms, a dielectric is not an insulator in the electrical sense.
It is a torsion moderator.

A dielectric:

  • Allows AMS tension alignment.
  • Suppresses vorton slip and large-scale reconfiguration.
  • Increases the permissible density of stored tension before breakdown.

Thus:

  • High-κ dielectrics = materials that allow tighter AMS tension packing.
  • Breakdown = forced topological failure of AMS alignment → plasma discharge.

This explains why:

  • Vacuum can be a dielectric.
  • Different materials radically change capacitance.
  • Dielectric heating occurs (micro-torsion dissipation in AMS).

4. Charging a Capacitor (Dynamic Behaviour)

When charging:

  1. The source attempts to equalise AMS tension.
  2. Vorton slip occurs in the external circuit.
  3. At the capacitor plates:
    • AMS tension accumulates spatially.
    • Slip is blocked across the dielectric.
  4. As tension builds:
    • The gradient opposing further reconfiguration increases.
  5. Current decreases smoothly to zero.

AMS interpretation of the charging curve:

  • Early time: easy AMS reconfiguration → high slip rate (high current).
  • Later time: tension saturation → increasing resistance to further alignment.
  • Final state: static AMS deformation → no current.

The capacitor is full when:

Additional AMS reconfiguration would require violating the dielectric’s torsion limits.

5. Discharging a Capacitor

On discharge:

  • The stored AMS tension configuration is released.
  • The dielectric no longer blocks equalisation.
  • Tension collapses back into background AMS state.
  • Coordinated vorton slip resumes in the circuit.

This produces:

  • A transient current pulse.
  • No intrinsic direction preference (depends on circuit topology).

Again:

Nothing “flows out” of the capacitor.
The AMS relaxes.

6. Capacitance Reinterpreted

Capacitance (C) becomes:

The ability of a given geometry + dielectric to hold AMS tension per unit imposed boundary difference.

Thus:

  • Large plate area → more AMS cross-section engaged.
  • Small separation → higher tension density.
  • Better dielectric → tighter torsion packing.

The classical formula:
C = εA / d

is reinterpreted as:

  • ε → AMS torsion compliance of the dielectric.
  • A → spatial extent of tension engagement.
  • d → distance over which tension must be held without slip.

7. Capacitors vs Batteries (Clarified)

Battery Capacitor
Stores chemical geometry that can impose AMS tension Stores spatial AMS deformation directly
Active re-pumping of gradient Passive tension retention
Sustains current Only supports transient reconfiguration

This cleanly explains why:

  • Capacitors respond instantly.
  • Batteries respond chemically.
  • Capacitors excel at AC smoothing and timing.

8. AC Behaviour (Preview)

In alternating tension:

  • The AMS deformation oscillates spatially.
  • Vorton slip reverses direction each cycle.
  • No net drift accumulates.

Thus:

Capacitors oppose changes in AMS tension configuration, not tension itself.

This naturally produces phase lag without invoking particles.

9. Summary

A capacitor is a device that captures and holds a shaped region of AMS tension in space, using geometry and material constraints to delay the natural equalisation of the substrate.

No charges are stored.
No particles pile up.
Only tension waits.

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