Josephson Junctions and Gravitational Waves
Scientists / Papers
Gary Stevenson, Giorgio Fontana
Cited In
PREPARATION - Studying the Enemy →Theories Citing This Reference (8)
CIA Possession of Ghost Murmur
The CIA has possessed and operated 'Ghost Murmur' technology for 10-15 years, and Stevenson's work is a public normalization or 'soft launch' of this existing capability.
Ether Theory
A hypothetical medium that permeates space and acts as the medium for the spread of electromagnetic waves.
Gravitational Laser (Gazer) Mechanism
Giorgio Fontana's 'Gazer' device uses a bilayer superconductor structure to convert photon energy into gravitons via spin-2 transitions, effectively creating a gravitational laser.
Gravitational Wave Communication Chip
A micro-scale device using superconducting Josephson junctions can generate detectable gravitational waves to carry information through obstacles that block electromagnetic signals.
Quantum Gravitational Sensing
Josephson junction arrays can detect gravitational ripples in the zero-point energy field (perturbations in the ether), enabling sensing of normally undetectable quantum phenomena
Quantum Universal Time
Quantum universal time clock gravity based time reference frame independent time dilation Gary Stevenson proposed solution
Scalar Gravity Wave Transition via Superconducting Junctions
A specific mechanism where a junction between Type 1 and Type 2 superconductors (S-wave junction) forces the transition of electromagnetic waves into gravity waves (gravitons), enabling propulsion and energy extraction.
SQUID Architecture Underlies All Quantum Technologies
The SQUID design (two Josephson junctions) is the fundamental architecture underlying not just quantum computers but all quantum technologies including quantum radar, astronomical detectors, and potentially classified surveillance systems. The speaker notes that China's 'quantum radar' and various detection arrays likely use this same SQUID-based architecture. This suggests a convergence of quantum technologies around Josephson junction physics, with applications spanning computing, sensing, communication, and potentially weapon systems.