Bipolar Trumpet Coils as QMU Toy Models for Black Hole Torsion Filaments and Polar Jets (Analog Torsion)

In the Aether Physics Model (APM) expressed in Quantum Measurement Units (QMU), galactic--center black holes are treated as pure Aether density configurations whose effective mass ledgers are sourced entirely by their host galaxies. Around these rotating Aether structures, torsion organizes into two reciprocal manifestations: magnetic torsion filaments associated with the magnetic charge ledger and electrostatic polar jets associated with large-scale potential differences in the electrostatic charge ledger.  This paper develops a unified QMU ledger for these effects and introduces a bipolar double-trumpet Tesla coil as a laboratory toy model of the black hole, accretion ring, and bipolar jet system.

The analysis is formulated as ``analog torsion.''  The same quantized Aether, the same curl unit, and the same QMU mass--energy and charge ledgers govern both the astrophysical configuration and the coil, so the torsion flow geometry is scale invariant in QMU even though the underlying ledgers differ by many orders of magnitude.  Using the length-density ledger $\Lambda^{\ast} = (M / m_{a})(\lambda_{C} / r)$, the torsion unit, its reciprocal winding unit, and the QMU charge-duality identity $\delta_{q} = e^{2} /{ e_\mathrm{emax}}^{2} = 8\pi\alpha$, we construct explicit, fully dimensionless torsion invariants for the filament and jet phases.  The magnetic filament invariant
\[
\Xi_{\mathrm{mag}} 
= 8\pi\alpha\,
\Lambda^{\ast}_{\mathrm{toroid}}
\left|
\frac{\partial \Lambda^{\ast}_{\mathrm{toroid}}}{\partial (r / \lambda_{C})}
\right|
\]
controls the onset of toroidal magnetic torsion filaments in the near-horizon region, while the electrostatic jet invariant
\[
\Xi_{\mathrm{elec}}
= \frac{1}{8\pi\alpha}\,
\Lambda^{\ast}_{\mathrm{axis}}
\left|
\frac{\partial \Lambda^{\ast}_{\mathrm{axis}}}{\partial (z / \lambda_{C})}
\right|
\left(
\frac{\Delta\Phi}{\Phi_{0}}
\right),
\qquad
\Phi_{0} = \frac{e^{2}}{4\pi\epsilon_{0}\lambda_{C}},
\]
controls the formation of axial electrostatic torsion channels along the polar directions.  Their product defines a total torsion allocation ledger
\[
\Xi_{0} \equiv \Xi_{\mathrm{mag}}\,\Xi_{\mathrm{elec}}
= \left(\frac{\Delta\Phi}{\Phi_{0}}\right)\times\mathcal{O}(1)
\approx 1,
\]
so the filament--jet reciprocity and three-phase torsion structure are predictions of the previously published QMU constants, not new adjustable parameters.

The bipolar double-trumpet Tesla coil implements the same torsion phase structure in the electron sector.  The horn ring and primary correspond to the black hole horizon and inner accretion ring, the two trumpet secondaries correspond to the bipolar polar jets, and the remote top loads correspond to distant Aether anchor regions.  In this toy model, the same invariants $\Xi_{\mathrm{mag}}$ and $\Xi_{\mathrm{elec}}$ govern whether the torsion budget is expressed as ringlike filaments, axial channels, or a mixed phase, but the underlying ledgers remain set by the electron mass and the fine structure $\alpha$, far from the galactic--center condition $M / r = m_{a} / \lambda_{C}$ with extremely small Aether fine structure.

Finally, the paper interprets polar jets as path-shortened Aether channels rather than ballistic outflows.  In both black holes and trumpet coils, null trajectories follow torsion-modified geodesics with effective coordinate length $d\ell_{\mathrm{tors}} = \chi(\Xi)\,d\ell_{0}$ and local photon-speed ledger $d\ell_{\mathrm{tors}} = F_{q}\lambda_{C}\,dt$, where $0 < \chi(\Xi) \leq 1$ is a dimensionless path-shortening factor.  We propose a QMU experimental program based on phase and latency measurements in the double-trumpet coil: by varying the input power and axial potential difference, one can move the coil through filament, jet, and mixed torsion phases and search for a power-dependent decrease in effective latency along the axial torsion channel that cannot be explained by ordinary RLC parameter drift.  The result is a falsifiable analog-torsion framework that links galactic-center torsion filaments, polar jets, and laboratory trumpet coils through a single QMU torsion ledger, without attempting to create a literal black hole and without requiring superluminal information transfer.