Faraday Paradox Experiment Protocol

Resonance Substrate Model — Experimental Series

Quicklinks#

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1. Objective#

To investigate paradox‑class induction behavior under rotating magnetic fields and stationary conductors, and to compare classical EM predictions with resonance‑substrate field responses.

2. Background#

Faraday’s Paradox describes a counterintuitive induction phenomenon where rotation of a magnet does not always induce the expected EMF in a stationary conductor.
This experiment adapts the classical setup into the Resonance Substrate Model to explore:

• field alignment
• resonance envelope deformation
• spin‑field coherence under rotation

3. Apparatus#

• rotating field source (physical or simulated)
• stationary conductive loop or substrate analog
• field sensors or substrate probes
• data acquisition system
• reference diagram: apparatus_diagram.svg

4. Procedure#

4.1 Setup#

1. Position the stationary conductor or substrate grid.
2. Align the rotating magnetic field source with the central axis.
3. Initialize measurement probes and baseline readings.

4.2 Execution#

1. Begin rotation at low angular velocity.
2. Record induced field values and resonance envelope activation.
3. Increase rotation speed in controlled increments.
4. Capture spin‑field alignment and diffusion behavior at each step.

4.3 Data Collection#

• induced EMF or substrate‑analog signal
• field vector snapshots
• resonance envelope activation maps
• rotation rate and stability metrics

5. Analysis#

Analysis is performed in analysis.ipynb, including:

• time‑series plots
• field vector visualizations
• comparison to classical EM predictions
• substrate‑specific deviations

6. Expected Outcomes#

• reproduction of paradox‑class induction behavior
• identification of resonance‑specific field responses
• insight into substrate alignment under rotational forcing

7. References#

See references.bib in the whitepaper directory.