Stealth Communications is expanding its Physics Division and is seeking multiple highly disciplined experimental physicist to join a team investigating vacuum degeneracy propulsion concepts rooted in Planck-scale dipole field structures and toroidal charge ring coherence.
The position involves experimental validation of collapse induced pressure gradients at the interface of quantized polarizable vacuum structures, exploring the hypothesis that local phase shifting of the vacuum state may yield net propulsion beyond the light-speed threshold.
Responsibilities
- Design, construct and operate toroidal EVO generation chambers utilizing multi-axis coherence field coils and vacuum-phase transducers
- Conduct phase aligned multi-resonator experiments to generate controlled vacuum collapse zones and assess induced pressure differential effects on matter inertia
- Engineer and test stacked AB-phase EVO geometries for bidirectional vacuum coupling and anomalous mass fluctuation
- Integrate structured magnetic vector potentials and longitudinal B-fields with entangled photon injection systems to modulate local spacetime curvature
- Develop measurement frameworks to quantify coherence length, phase displacement,and group velocity modulation in vacuum-engineered environments
- Simulate and experimentally validate nullification of electron spin precession under dynamic electric/magnetic field alignment using multi-stage toroidal drivers
- Investigate photon-spin/magnetic vector interactions to engineer localized spacetime displacement fields through vacuum polarization modulation
- Lead investigations into photonic-magnetic coupling for energy localization, metric gradient generation, and impulse vector field propagation
- Analyze field data to characterize system behavior under both near-vacuum and ultra-high vacuum regimes, correlating metric field distortion with observable propulsion
- Work collaboratively with theorists, field engineers, and plasma specialists to refine gravitoelectric permittivity differential models
- Design and validate push-pull dipole propagation cycles through phase-locked electromagnetic standing wave fields and tunable low-inertia plasmoid confinement
- Maintain rigorous safety, containment, and discharge control procedures in high-voltage and sub-Planck scale quantum fluctuation testing environments
- Document all findings (encrypted technical logs); brief compartmented leadership teams on significant phase transitions, energy anomalies, and propagation asymmetries.
Qualifications
- Active TS/SCI clearance preferred; applicants with prior SCI or SAP access given priority
- Ph.D. in Theoretical Physics, Plasma Physics, Quantum Electrodynamics, Field Theory OR Applied Electromagnetics. Postdoctoral research in advanced propulsion or vacuum physics strongly preferred
- Minimum 10 years of hands-on experience in one or more of the following: (1) High-voltage vacuum experimentation (sub-mTorr to UHV regimes) (2) Toroidal or polyphase field coil systems (multi-layer resonance tuning) (3) Photonic entanglement apparatus interfaced with magnetic field lattices
- Demonstrated mastery of: (1) Aharonov-Bohm phase control, (2) Electron spin precession nullification, (3) Plasmoid confinement techniques, and (4) Time-varying magnetic vector potentials (A-fields)
- Familiarity with or formal training in: (1) Surreal number theory, dyadic symmetry, or JANUS vacuum models, (2) Vacuum birefringence and quantum optics in curved spacetime, (3) de Broglie–Bohm mechanics, particularly wavefunction coherence in phase-modified vacua
- Additional experience requirements: (1) High-speed pulsed power systems (ns-to-μs range), (2) AB-effect interferometry and coherence length diagnostics (λ²/2Δλ), (3) Computational modeling of exotic matter–field interactions using FDTD, COMSOL Multiphysics, or custom solvers
Starting salary: $400,000 w/ sign-on bonus of $400,000 + Relocation Assistance via Stealth Real Estate Operations.
To apply, send us a DM or apply on LinkedIn with a brief, discreet introduction and a redacted version of your work portfolio or white paper on related topics.