MH370 Non Equilibrium Plasma Orb
The thermal signature of the MH370 orbs reveals a distinctive non-equilibrium plasma configuration fundamentally different from conventional fusion approaches. In equilibrium plasmas—typical of tokamak confinement—temperatures remain uniform throughout the volume, producing homogeneous thermal signatures. The MH370 orbs, however, display a clear temperature gradient: a stable green-orange core region contrasting with cooler blue periphery. This structure matches Robert Bussard's polywell innovation, where electrons are magnetically confined to create a negative potential well at the center, allowing ions to recirculate rather than escaping. The 'whiffle ball' configuration—where point cusps rather than line cusps control particle losses—produces precisely this non-uniform thermal profile. The orange slice pattern visible in thermal imagery suggests localized high-energy regions where fusion reactions concentrate, surrounded by cooler zones where magnetic insulation prevents wall contact. This differs fundamentally from equilibrium systems where heat distributes evenly. The observation aligns with Bussard's 1994-2005 research achieving beta-one conditions, suggesting the orbs represent operational implementations of the suppressed polywell architecture rather than conventional tokamak derivatives.
The MH370 orbs' thermal signatures display non-equilibrium plasma characteristics—stable hot cores with cooler peripheries—matching Robert Bussard's polywell whiffle ball configuration where magnetically-confined electrons create negative potential wells enabling aneutronic fusion.
Key Insight
This theory is part of the MH370 investigation — the central case study of the 4Orbs research. It connects directly to satellite footage, radar data, and physical evidence surrounding the disappearance of Malaysia Airlines Flight 370 with 239 people aboard.
Supporting Points
- Stable heat signature
- Green orange slice uniform
- Non equilibrium texture
Critical Context
Non-equilibrium plasma represents a distinct regime from thermal equilibrium confinement. In conventional tokamaks, collisional processes rapidly thermalize particle distributions toward Maxwellian equilibria. Non-equilibrium approaches attempt to maintain population inversions—energetic ions in cooler electron backgrounds—to enhance fusion reactivity at lower bulk temperatures. Bussard's IEC (Inertial Electrostatic Confinement) concept, realized in the WB-series devices, demonstrated this principle with electron-confined virtual cathodes. Critics note that non-equilibrium systems face stability challenges: maintaining separated populations against collisional thermalization requires careful parameter control. The plasma physics community remains divided on whether non-equilibrium approaches can achieve net energy gain. Recent Helion Energy results claiming to approach breakeven with field-reversed configuration—another non-equilibrium approach—suggest continued interest, though peer-reviewed validation remains pending.
How This Connects
The non-equilibrium signature connects to the broader fusion suppression narrative: the Reagan-era down-selection to tokamaks eliminated research lines capable of producing exactly this plasma topology. The orbs' thermal characteristics suggest development continued in classified channels, with MH370 potentially representing a field demonstration of aneutronic fusion propulsion systems withheld from public science.
Claims from This Video
1 over r squared density squared equals 1 over r fourth spherical convergence fusion core.
Irving Langmuir Katherine Blodgett 1924 space charge paper concentric flows spheres.
Elmore Tuck Watson 1959 Los Alamos inertial electrostatic confinement plasma spherical grid.
Negative potential Thomas Thompson Brown effect asymmetric capacitors radial.
Magnetic field contains electrons electrons weigh nothing ions heavier.
Grid electrons 100000 transitions fusion ion population grid melt problem.
Whiffle ball configuration plasma leak trapped magnetic fields flow back middle.
100 kilovolt well departure neutrality one part million density.
Quasi sphere topology configuration patented polyhedron coils edges even faces.
Doughnut plasma touch walls avoidable donut shaped stars none.