Electrogravitics: Difference between revisions

Electrogravitics is the study of interactions between high-voltage electric fields and gravitational forces, aiming to generate propulsion or modify gravitational effects through electrical means. Central to the field is the Biefeld-Brown effect: a unidirectional thrust produced by asymmetric capacitors under high voltage that appears to depend on the mass of the system.

In Tho'ra vehicles, electrogravitic systems provide fine attitude control, supplementary lift, and maneuvering thrust for the Magneto Speeder and Star Speeder.

Historical Development

Theoretical Basis

The Biefeld-Brown Effect

An asymmetric capacitor (electrodes of different geometry/mass) under high DC voltage produces a net force toward the smaller electrode. The empirical force relationship from the declassified GRG 013/56 report (Project Winterhaven): ^[2]

${\displaystyle F_{BB}=k\cdot C\cdot V^{2}\cdot A_{G}}$

where ${\displaystyle k}$ is a material-dependent electrokinetic coupling constant, ${\displaystyle C}$ is capacitance, ${\displaystyle V}$ is applied voltage, and ${\displaystyle A_{G}}$ is a geometric asymmetry factor. The V² scaling is consistent with electrostatic energy density and has been independently confirmed. See Biefeld-Brown Effect for full analysis including modern vacuum test results.

For detailed biography, see Thomas Townsend Brown.

Asymmetric Capacitor Force

For an idealized asymmetric parallel-plate capacitor:

${\displaystyle F={\frac {\epsilon _{0}\epsilon _{r}AV^{2}}{2d^{2}}}\cdot \eta _{\text{coupling}}}$

where:

• ${\displaystyle \epsilon _{0}=8.854\times 10^{-12}\,{\text{F/m}}}$ (vacuum permittivity)
• ${\displaystyle \epsilon _{r}}$ = relative permittivity of dielectric
• ${\displaystyle A}$ = electrode area (m²)
• ${\displaystyle V}$ = applied voltage (V)
• ${\displaystyle d}$ = plate separation (m)
• ${\displaystyle \eta _{\text{coupling}}}$ = gravity-coupling efficiency factor (empirical, ~10⁻⁶ to 10⁻⁴)

For barium titanate dielectric (${\displaystyle \epsilon _{r}\approx 1{,}200}$), ${\displaystyle A=0.1\,{\text{m}}^{2}}$, ${\displaystyle V=100\,{\text{kV}}}$, ${\displaystyle d=1\,{\text{cm}}}$:

${\displaystyle F={\frac {8.854\times 10^{-12}\times 1200\times 0.1\times (10^{5})^{2}}{2\times (0.01)^{2}}}\times \eta \approx 5{,}312\times \eta \,{\text{N}}}$

Even with ${\displaystyle \eta =10^{-4}}$, this yields ~0.5 N — measurable and useful for attitude control.

Vacuum Thrust Measurements

Critical to distinguishing electrogravitics from ionic wind: thrust must persist in vacuum. Brown's 1965 patent data and subsequent NASA-adjacent tests report: ^[3]

The vacuum thrust question remains open and contested. The Star Speeder's design accounts for this by using electrogravitics only as supplementary assist, not primary propulsion.

Subquantum Kinetics Model

Paul LaViolette's subquantum kinetics provides an alternative framework via reaction-diffusion equations describing subquantum etheric fluxes: ^[4]

${\displaystyle {\frac {\partial X}{\partial t}}=D_{X}\nabla ^{2}X+A-(B+1)X+X^{2}Y-CX^{3}}$

where ${\displaystyle X,Y}$ represent subquantum particle concentrations whose gradients influence gravitational potential. This model predicts that electric field polarization of matter creates a gravitational dipole moment.

Casimir-Electrogravitic Interface

The Casimir force between conducting plates:

${\displaystyle F_{\text{Casimir}}={\frac {\pi ^{2}\hbar c}{240}}{\frac {A}{L^{4}}}}$

shares mathematical structure with electrogravitic force expressions. At nanoscale separations, Casimir and electrogravitic effects may be manifestations of the same vacuum physics:

${\displaystyle F_{\text{total}}=F_{\text{Casimir}}+F_{\text{electrostatic}}+F_{\text{EG}}={\frac {\pi ^{2}\hbar cA}{240L^{4}}}+{\frac {\epsilon _{0}AV^{2}}{2L^{2}}}+F_{\text{coupling}}(V,m,L)}$

The DARPA Casimir Effect program (funded 2018+) investigates this overlap for potential propulsion applications.

Engineering Implementation

Magneto Speeder Integration

The Magneto Speeder uses electrogravitic arrays for:

• Attitude control: 8 asymmetric capacitor panels (4 dorsal, 4 ventral) provide roll/pitch/yaw torques
• Supplementary lift: During hover, electrogravitic lift reduces load on magnetogravitic drive by 5–15%
• Vibration damping: High-frequency voltage modulation counteracts mechanical oscillations

System specifications:

• Voltage: 100 kV DC (variable)
• Dielectric: Barium titanate / metamaterial composite
• Total array mass: ~25 kg
• Power consumption: ~500 W continuous
• Estimated supplementary thrust: 10–50 N (attitude) / up to 200 N (emergency boost)

Star Speeder Integration

The Star Speeder uses refined electrogravitic systems for:

• Artificial gravity: Crew comfort during transit (combined with magnetogravitic fields)
• Precision docking: Sub-millimeter positioning control
• Radiation field shaping: Modifying local field geometry to deflect charged particles

Cross-Disciplinary Applications

Electrogravitics Across Disciplines

Discipline	Key Equation	Role
Electrostatics	${\displaystyle F={\frac {kq_{1}q_{2}}{r^{2}}}}$ (Coulomb)	Basis for charge-induced asymmetric force
General Relativity	${\displaystyle g_{00}\approx 1-{\frac {2\Phi }{c^{2}}}+{\frac {\epsilon _{0}E^{2}}{2\rho c^{2}}}}$	Metric modification by electric field energy
QED	Virtual photon polarization in strong E-fields	Enhanced gravity coupling mechanism
Aerospace	${\displaystyle F={\frac {\epsilon _{0}AV^{2}}{2d^{2}}}\cdot \eta }$	Thrust calculation for capacitor arrays
Plasma Physics	Ionic wind: ${\displaystyle v=\mu E}$	Disambiguation from true electrogravitic effects
HV Engineering	Dielectric breakdown: ${\displaystyle E_{\text{max}}=V/d}$	Material limits on achievable voltages
Materials Science	Piezoelectric: ${\displaystyle d=\Delta l/(V\cdot t)}$	Advanced dielectric development

Theoretical Foundations

The electrogravitic effect, if real, connects to several theoretical frameworks:

The distinction between electrogravitics (high-voltage, Biefeld-Brown lineage) and magnetogravitics (rotating mass/superconductor, Li-Torr lineage) is important: they use different physical mechanisms but both aim to couple electromagnetic and gravitational fields.

See Also

• Biefeld-Brown Effect
• Thomas Townsend Brown
• Project Winterhaven
• Gravitoelectromagnetism
• Kaluza-Klein Unification
• Ning Li
• Tate Experiment
• Pais Effect
• Heim Theory
• Woodward Effect
• Magnetogravitics
• Magnetohydrodynamic
• MHD Core
• Magneto Speeder
• Star Speeder
• Electrogravitic Tech

References